Computer-readable storage medium, image recognition apparatus, image recognition system, and image recognition method

ABSTRACT

First, a plurality of vertices of a contour of an object or of a design are detected from an image. Then, a predetermined number of division points are generated on each of sides connecting the plurality of detected vertices, so as to divide each side of at least one pair of two opposing sides into unequal parts. Then, a plurality of sample points are determined on the basis of straight lines connecting the division points on the two opposing sides to one another, and on the basis of pixel values of the sample points, it is determined whether or not a predetermined object or design is displayed in an area surrounded by the plurality of vertices in the image.

CROSS REFERENCE TO RELATED APPLICATION

The disclosure of Japanese Patent Application No. 2011-039030, filed onFeb. 24, 2011, is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a computer-readable storage medium, animage recognition apparatus, an image recognition system, and an imagerecognition method, for detecting a predetermined capturing target froman image captured by capturing means.

2. Description of the Background Art

Conventionally, there is a technique of detecting a predeterminedcapturing target from an image captured by capturing means such as acamera (a captured image). For example, Non-Patent Literature 1 statesthat in augmented reality technology, an image recognition process isperformed on a marker included in an image captured by a camera.Non-Patent Literature 1 states that connected regions are extracted bybinarizing the captured image using a fixed threshold, and regions ofappropriate sizes and shapes are selected, from among the extractedconnected regions, to be marker candidates. Then, the marker is detectedby performing pattern matching on the marker candidates.

-   [Non-Patent Literature 1] Hirokazu Kato, Mark Billinghurst, Koichi    Asarco, Keihachiro Tachibana, “An Augmented Reality System and its    Calibration based on Marker Tracking”, Journal of the Virtual    Reality Society of Japan, vol. 4, no. 4, 1999

The detection method of a marker described in Non-Patent Literature 1cannot necessarily detect a marker with high accuracy or a smallprocessing load in various states (e.g., a bright state; a dark state;the state where part of the marker is hidden by, for example, a user'sfinger; the state where the marker does not face the camera in afull-face manner; and the state where a strong light is reflected by themarker).

In addition, the detection method of a marker described in Non-PatentLiterature 1 cannot prevent a slight deviation of the position of thedetected position of the marker.

SUMMARY OF THE INVENTION

Therefore, it is an object of the present invention to provide acomputer-readable storage medium, an image recognition apparatus, animage recognition system, and an image recognition method that arecapable of detecting a predetermined object or design from an image withhigh accuracy or a small processing load, and to provide acomputer-readable storage medium, an image recognition apparatus, animage recognition system, and an image recognition method that arecapable of preventing or reducing a slight deviation of the position ofa predetermined object or design that has been detected.

To achieve the above object, the present invention may employ thefollowing configurations.

A first configuration example is a computer-readable storage mediumhaving stored thereon an image recognition program causing a computer ofan information processing apparatus to function as image acquisitionmeans, vertex detection means, division point generation means, samplepoint determination means, and distinction means.

The image acquisition means acquires an image. The vertex detectionmeans detects from the image a plurality of vertices of a contour of anobject or of a design. The division point generation means generates apredetermined number of division points on each of sides connecting theplurality of vertices to each other, so as to divide each side of atleast one pair of two opposing sides into unequal parts. The samplepoint determination means determines a plurality of sample points on thebasis of straight lines connecting the division points on the twoopposing sides to one another. The distinction means, on the basis ofpixel values of the sample points, determines whether or not apredetermined object or design is displayed in an area surrounded by theplurality of vertices in the image.

Based on the first configuration example, it is possible to distinguisha predetermined object or design with accuracy.

It should be noted that as a variation, the division point generationmeans may generate the division points on each side of at least one pairof two opposing sides such that the closer to one end of each side ofthe two opposing sides, the denser the division points.

Based on the variation, it is possible to distinguish the predeterminedobject or design with improved accuracy.

In addition, as another variation, the division point generation meansmay divide each side of at least one pair of two opposing sides intounequal parts in accordance with a ratio of: a distance between one endof one side of the two opposing sides and a corresponding one end of theother side; to a distance between the other ends.

Based on the variation, it is possible to distinguish the predeterminedobject or design with improved accuracy.

In addition, as another variation, the image recognition program mayfurther cause the computer to function as determination means fordetermining whether or not, among the plurality of sides connecting theplurality of vertices to each other, given two opposing sides areparallel to each other, and the division point generation means mayinclude: equal division means for, when the determination means hasdetermined that any two opposing sides are parallel to each other,generating the division points so as to divide each side of the twoopposing sides into equal parts; and unequal division means for, whenthe determination means has determined that any two opposing sides arenot parallel to each other, generating the division points so as todivide each side of the two opposing sides into unequal parts.

Based on the variation, it is possible to distinguish the predeterminedobject or design with improved accuracy.

In addition, as another variation, the division point generation meansmay include: first vanishing point calculation means for calculating afirst vanishing point, the first vanishing point being an intersectionof straight lines extending from a first side and a second side,respectively, the first side and the second side opposing each other;second vanishing point calculation means for calculating a secondvanishing point, the second vanishing point being an intersection ofstraight lines extending from a third side and a fourth side,respectively, the third side and the fourth side opposing each other;second straight line calculation means for calculating a second straightline, the second straight line being parallel to a first straight lineconnecting the first vanishing point to the second vanishing point, thesecond straight line passing through the vertex furthest from the firststraight line; first equal division means for, on a line segmentconnecting an intersection of the straight line passing through thefirst side and the second straight line to an intersection of thestraight line passing through the second side and the second straightline, generating a plurality of first equal division points so as todivide the line segment into equal parts; second equal division meansfor, on a line segment connecting an intersection of the straight linepassing through the third side and the second straight line to anintersection of the straight line passing through the fourth side andthe second straight line, generating a plurality of second equaldivision points so as to divide the line segment into equal parts; firstgeneration means for, on the basis of straight lines connecting thefirst vanishing point to the first equal division points, generating thedivision points on each of the third side and the fourth side so as todivide each of the third side and the fourth side into unequal parts;and second generation means for, on the basis of straight linesconnecting the second vanishing point to the second equal divisionpoints, generating the division points on each of the first side and thesecond side so as to divide each of the first side and the second sideinto unequal parts.

Based on the variation, it is possible to distinguish the predeterminedobject or design with improved accuracy.

It should be noted that the image recognition program can be stored in agiven computer-readable storage medium (e.g., a flexible disk, a harddisk, an optical disk, a magnetic optical disk, a CD-ROM, a CD-R, amagnetic tape, a semiconductor memory card, a ROM, and a RAM).

A second configuration example is an image recognition apparatusincluding: image acquisition means for acquiring an image; vertexdetection means for detecting from the image a plurality of vertices ofa contour of an object or of a design; division point generation meansfor generating a predetermined number of division points on each ofsides connecting the plurality of vertices to each other, so as todivide each side of at least one pair of two opposing sides into unequalparts; sample point determination means for determining a plurality ofsample points on the basis of straight lines connecting the divisionpoints on the two opposing sides to one another; and distinction meansfor, on the basis of pixel values of the sample points, determiningwhether or not a predetermined object or design is displayed in an areasurrounded by the plurality of vertices in the image.

A third configuration example is an image recognition method including:an image acquisition step of acquiring an image; a vertex detection stepof detecting from the image a plurality of vertices of a contour of anobject or of a design; a division point generation step of generating apredetermined number of division points on each of sides connecting theplurality of vertices to each other, so as to divide each side of atleast one pair of two opposing sides into unequal parts; a sample pointdetermination step of determining a plurality of sample points on thebasis of straight lines connecting the division points on the twoopposing sides to one another; and a distinction step of, on the basisof pixel values of the sample points, determining whether or not apredetermined object or design is displayed in an area surrounded by theplurality of vertices in the image.

A fourth configuration example is an image recognition system including:image acquisition means for acquiring an image; vertex detection meansfor detecting from the image a plurality of vertices of a contour of anobject or of a design; division point generation means for generating apredetermined number of division points on each of sides connecting theplurality of vertices to each other, so as to divide each side of atleast one pair of two opposing sides into unequal parts; sample pointdetermination means for determining a plurality of sample points on thebasis of straight lines connecting the division points on the twoopposing sides to one another; and distinction means for, on the basisof pixel values of the sample points, determining whether or not apredetermined object or design is displayed in an area surrounded by theplurality of vertices in the image.

A fifth configuration example is an image recognition system includingan image recognition apparatus and a marker in which a design is drawn.The image recognition apparatus includes: a capturing section forcapturing the marker; image acquisition means for acquiring an imagefrom the capturing section; vertex detection means for detecting fromthe image a plurality of vertices of a contour of the marker or of thedesign; division point generation means for generating a predeterminednumber of division points on each of sides connecting the plurality ofvertices to each other, so as to divide each side of at least one pairof two opposing sides into unequal parts; sample point determinationmeans for determining a plurality of sample points on the basis ofstraight lines connecting the division points on the two opposing sidesto one another; and distinction means for, on the basis of pixel valuesof the sample points, determining whether or not a predetermined designis displayed in an area surrounded by the plurality of vertices in theimage.

Based on the above configuration examples, it is possible to detect apredetermined object or design from an image with high accuracy.

These and other objects, features, aspects and advantages of the presentinvention will become more apparent from the following detaileddescription of the present invention when taken in conjunction with theaccompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a front view of a game apparatus 10 in an open state;

FIG. 2A is a left side view of the game apparatus 10 in a closed state;

FIG. 2B is a front view of the game apparatus 10 in the closed state;

FIG. 2C is a right side view of the game apparatus 10 in the closedstate;

FIG. 2D is a rear view of the game apparatus 10 in the closed state;

FIG. 3 is a block diagram showing the internal configuration of the gameapparatus 10;

FIG. 4 is a diagram showing an image displayed on an upper LCD 22;

FIG. 5 is a diagram showing a marker 50;

FIG. 6 is a diagram showing a captured real image captured by an outercapturing section (left) 23 a or an outer capturing section (right) 23b;

FIG. 7 is a diagram showing the order of selecting a marked pixel in thecaptured real image;

FIG. 8 is a diagram illustrating a determination method of an edgedetermination threshold;

FIG. 9 is a diagram illustrating the determination method of the edgedetermination threshold;

FIG. 10 is a diagram illustrating the determination method of the edgedetermination threshold;

FIG. 11 is a diagram illustrating the determination method of the edgedetermination threshold;

FIG. 12 is a diagram illustrating the determination method of the edgedetermination threshold;

FIG. 13 is a diagram illustrating an edge tracking process;

FIG. 14 is a diagram illustrating the edge tracking process;

FIG. 15 is a diagram illustrating the edge tracking process;

FIG. 16 is a diagram illustrating the edge tracking process;

FIG. 17 is a diagram illustrating the edge tracking process;

FIG. 18 is a diagram illustrating the edge tracking process;

FIG. 19 is a diagram illustrating the edge tracking process;

FIG. 20 is a diagram illustrating the edge tracking process;

FIG. 21 is a diagram illustrating the edge tracking process;

FIG. 22 is a diagram illustrating a straight line calculation process;

FIG. 23 is a diagram illustrating the straight line calculation process;

FIG. 24 is a diagram illustrating the straight line calculation process;

FIG. 25 is a diagram illustrating the straight line calculation process;

FIG. 26 is a diagram illustrating the straight line calculation process;

FIG. 27 is a diagram illustrating the straight line calculation process;

FIG. 28 is a diagram illustrating the straight line calculation process;

FIG. 29 is a diagram illustrating the straight line calculation process;

FIG. 30 is a diagram illustrating the straight line calculation process;

FIG. 31 is a diagram illustrating the straight line calculation process;

FIG. 32 is a diagram illustrating the straight line calculation process;

FIG. 33 is a diagram illustrating the straight line calculation process;

FIG. 34 is a diagram illustrating the straight line calculation process;

FIG. 35 is a diagram illustrating the straight line calculation process;

FIG. 36 is a diagram illustrating the straight line calculation process;

FIG. 37 is a diagram illustrating the straight line calculation process;

FIG. 38 is a diagram illustrating the straight line calculation process;

FIG. 39 is a diagram illustrating the straight line calculation process;

FIG. 40 is a diagram illustrating the straight line calculation process;

FIG. 41 is a diagram illustrating the straight line calculation process;

FIG. 42 is a diagram illustrating a vertex calculation process;

FIG. 43 is a diagram illustrating the vertex calculation process;

FIG. 44 is a diagram illustrating an exclusion condition A in a roughdistinction process;

FIG. 45 is a diagram illustrating an exclusion condition 13 in the roughdistinction process;

FIG. 46 is a diagram illustrating an exclusion condition C in the roughdistinction process;

FIG. 47 is a diagram illustrating an exclusion condition D in the roughdistinction process;

FIG. 48 is a diagram illustrating pattern definition data used in adesign distinction process;

FIG. 49 is a diagram illustrating the pattern definition data used inthe design distinction process;

FIG. 50 is a diagram showing a captured real image including the marker50;

FIG. 51 is a diagram showing an example of a determination method of thepositions of sample points in the captured real image;

FIG. 52 is a diagram illustrating a first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 53 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 54 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 55 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 56 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 57 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 58 is a diagram illustrating the first determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 59 is a diagram illustrating a second determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 60 is a diagram illustrating the second determination method ofdetermining the positions of the sample points in the captured realimage;

FIG. 61 is a diagram illustrating the design distinction processperformed when the contours and the vertices of the marker have not beendetected from a current captured real image;

FIG. 62 is a diagram illustrating the design distinction processperformed when the contours and the vertices of the marker have not beendetected from the current captured real image;

FIG. 63 is a diagram illustrating a marker position correction process;

FIG. 64 is a diagram illustrating the marker position correctionprocess;

FIG. 65 is a diagram illustrating the marker position correctionprocess;

FIG. 66 is a diagram for explaining the reason why the sizes of athreshold D1 and a threshold D2 are changed in accordance with the sizeof the marker in a captured real image;

FIG. 67 is a diagram for explaining the reason why the sizes of thethreshold D1 and the threshold D2 are changed in accordance with thesize of the marker in the captured real image;

FIG. 68 is a diagram showing a determination method of the threshold D1;

FIG. 69 is a diagram showing a determination method of the threshold D2;

FIG. 70 is a diagram illustrating a variation of the marker positioncorrection process;

FIG. 71 is a diagram illustrating another variation of the markerposition correction process;

FIG. 72 is a diagram illustrating a determination method of thecorrespondence relationships between markers;

FIG. 73 is a memory map of a main memory 32;

FIG. 74 is a flow chart showing the overall flow of an image recognitionprocess;

FIG. 75 is a flow chart showing the flow of a contour detection process;

FIG. 76 is a flow chart showing the flow of a vertex detection process;

FIG. 77 is a flow chart showing the flow of the rough distinctionprocess;

FIG. 78 is a flow chart showing the flow of the design distinctionprocess; and

FIG. 79 is a flow chart showing the flow of the marker positioncorrection process.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

(Configuration of Game Apparatus)

A description is given below of a game apparatus according to anembodiment of the present invention. A game apparatus 10 is a hand-heldgame apparatus. As shown in FIG. 1 and FIGS. 2A through 2D, the gameapparatus 10 includes a lower housing 11 and an upper housing 21. Thelower housing 11 and the upper housing 21 are connected to each other soas to be openable and closable in a folding manner (foldable).

(Description of Lower Housing)

As shown in FIG. 1 and FIGS. 2A through 2D, the lower housing 11includes a lower liquid crystal display (LCD) 12, a touch panel 13,operation buttons 14A through 14L, an analog stick 15, LEDs 16A and 16B,an insertion slot 17, and a microphone hole 18.

The touch panel 13 is mounted on the screen of the lower LCD 12. Theinsertion slot 17 (a dashed line shown in FIGS. 1 and 2D) is provided onthe upper side surface of the lower housing 11 so as to accommodate astylus 28.

The cross button 14A (direction input button 14A), the button 14B, thebutton 14C, the button 14D, the button 14E, the power button 14F, theselect button 14J, the home button 14K, and the start button 14L areprovided on the inner surface (main surface) of the lower housing 11.

The analog stick 15 is a device for indicating a direction.

The microphone hole 18 is provided on the inner surface of the lowerhousing 11. Underneath the microphone hole 18, a microphone 42 (see FIG.3) is provided as the sound input device described later.

As shown in FIGS. 2B and 2D, the L button 14G and the R button 14H areprovided on the upper side surface of the lower housing 11. Further, asshown in FIG. 2A, the sound volume button 14I is provided on the leftside surface of the lower housing 11 so as to adjust the sound volume ofa loudspeaker 43 of the game apparatus 10.

As shown in FIG. 2A, a cover section 11C is provided on the left sidesurface of the lower housing 11 so as to be openable and closable.Inside the cover section 11C, a connector is provided for electricallyconnecting the game apparatus 10 and a data storage external memory 45.

As shown in FIG. 2D, on the upper side surface of the lower housing 11,an insertion slot 11D is provided, into which an external memory 44 isto be inserted.

As shown in FIGS. 1 and 2C, the first LED 16A is provided on the lowerside surface of the lower housing 11 so as to notify a user of theon/off state of the power supply of the game apparatus 10. Further, thesecond LED 16B is provided on the right side surface of the lowerhousing 11 so as to notify the user of the establishment state of thewireless communication of the game apparatus 10. The game apparatus 10is capable of wirelessly communicating with other devices, and awireless switch 19 is provided on the right side surface of the lowerhousing 11 so as to enable/disable the function of the wirelesscommunication (see FIG. 2C).

(Description of Upper Housing)

As shown in FIG. 1 and FIGS. 2A through 2D, the upper housing 21includes an upper liquid crystal display (LCD) 22, an outer capturingsection 23 (an outer capturing section (left) 23 a and an outercapturing section (right) 23 b), an inner capturing section 24, a 3Dadjustment switch 25, and a 3D indicator 26.

The upper LCD 22 is a display device capable of displaying astereoscopically visible image. Specifically, the upper LCD 22 is aparallax barrier type display device capable of displaying an imagestereoscopically visible with the naked eye. The upper LCD 22 allows theuser to view the left-eye image with their left eye, and the right-eyeimage with their right eye, using the parallax barrier. This makes itpossible to display an image giving the user a stereoscopic effect (astereoscopic image). Further, the upper LCD 22 is capable of disablingthe parallax barrier. When disabling the parallax barrier, the upper LCD22 is capable of displaying an image in a planar manner. Thus, the upperLCD 22 is a display device capable of switching between: a stereoscopicdisplay mode for displaying a stereoscopic image; and a planar displaymode for displaying an image in a planar manner (displaying a planarview image). The switching of the display modes is performed by, forexample, the 3D adjustment switch 25 described later.

The “outer capturing section 23” is the collective term of the twocapturing sections (23 a and 23 b) provided on an outer surface 21D ofthe upper housing 21. The outer capturing section (left) 23 a and theouter capturing section (right) 23 b can be used as a stereo camera,depending on the program executed by the game apparatus 10.

The inner capturing section 24 is provided on the inner surface 21B ofthe upper housing 21, and functions as a capturing section having acapturing direction that is the same as the inward normal direction ofthe inner surface.

The 3D adjustment switch 25 is a slide switch, and is used to switch thedisplay modes of the upper LCD 22 as described above. The 3D adjustmentswitch 25 is also used to adjust the stereoscopic effect of astereoscopically visible image (stereoscopic image) displayed on theupper LCD 22. A slider 25 a of the 3D adjustment switch 25 is slidableto a given position in a predetermined direction (the up-downdirection), and the display mode of the upper LCD 22 is set inaccordance with the position of the slider 25 a. Further, the view ofthe stereoscopic image is adjusted in accordance with the position ofthe slider 25 a.

The 3D indicator 26 is an LED that indicates whether or not the upperLCD 22 is in the stereoscopic display mode.

In addition, speaker holes 21E are provided on the inner surface of theupper housing 21. A sound from the loudspeaker 43 described later isoutput through the speaker holes 21E.

(Internal Configuration of Game Apparatus 10)

Next, with reference to FIG. 3, a description is given of the internalconfiguration of the game apparatus 10. As shown in FIG. 3, the gameapparatus 10 includes, as well as the components described above,electronic components, such as an information processing section 31, amain memory 32, an external memory interface (external memory I/F) 33, adata storage external memory I/F 34, a data storage internal memory 35,a wireless communication module 36, a local communication module 37, areal-time clock (RTC) 38, an acceleration sensor 39, a power circuit 40,and an interface circuit (I/F circuit) 41.

The information processing section 31 includes a central processing unit(CPU) 311 that executes a predetermined program, a graphics processingunit (GPU) 312 that performs image processing, and a video RAM (VRAM)313. The CPU 311 executes a program stored in a memory (e.g., theexternal memory 44 connected to the external memory I/F 33, or the datastorage internal memory 35) included in the game apparatus 10, andthereby performs processing corresponding to the program. It should benoted that the program executed by the CPU 311 may be acquired fromanother device by communication with said another device. The GPU 312generates an image in accordance with an instruction from the CPU 311,and draws the image in the VRAM 313. The image drawn in the VRAM 313 isoutput to the upper LCD 22 and/or the lower LCD 12, and the image isdisplayed on the upper LCD 22 and/or the lower LCD 12.

The external memory I/F 33 is an interface for establishing a detachableconnection with the external memory 44. The data storage external memoryI/F 34 is an interface for establishing a detachable connection with thedata storage external memory 45.

The main memory 32 is a volatile storage device used as a work area or abuffer area of (the CPU 311 of) the information processing section 31.

The external memory 44 is a nonvolatile storage device for storing theprogram and the like executed by the information processing section 31.The external memory 44 is composed of, for example, a read-onlysemiconductor memory.

The data storage external memory 45 is composed of a readable/writablenon-volatile memory (e.g., a NAND flash memory), and is used to storegiven data.

The data storage internal memory 35 is composed of a readable/writablenon-volatile memory (e.g., a NAND flash memory), and is used to storepredetermined data. For example, the data storage internal memory 35stores data and/or programs downloaded by wireless communication throughthe wireless communication module 36.

The wireless communication module 36 has the function of establishingconnection with a wireless LAN by, for example, a method based on theIEEE 802.11.b/g standard. Further, the local communication module 37 hasthe function of wirelessly communicating with another game apparatus ofthe same type by a predetermined communication method (e.g.,communication using an independent protocol, or infrared communication).

The acceleration sensor 39 detects the magnitudes of accelerations inthe directions of straight lines along three axial (x, y, and z axes)directions (linear accelerations), respectively. The informationprocessing section 31 can receive data representing the accelerationsdetected by the acceleration sensor 39 (acceleration data), and detectthe orientation and the motion of the game apparatus 10.

The RTC 38 counts time, and outputs the counted time to the informationprocessing section 31. The information processing section 31 calculatesthe current time (date) on the basis of the time counted by the RTC 38.The power circuit 40 controls the power from the power supply (arechargeable battery) of the game apparatus 10, and supplies power toeach component of the game apparatus 10.

The touch panel 13, the microphone 42, and the loudspeaker 43 areconnected to the I/F circuit 41. The I/F circuit 41 includes: a soundcontrol circuit that controls the microphone 42 and the loudspeaker 43(amplifier); and a touch panel control circuit that controls the touchpanel 13. For example, the sound control circuit performs A/D conversionand D/A conversion on a sound signal, and converts the sound signal tosound data in a predetermined format. The touch panel control circuitgenerates touch position data in a predetermined format on the basis ofa signal from the touch panel 13, and outputs the touch position data tothe information processing section 31. The information processingsection 31 acquires the touch position data, and thereby recognizes theposition at which an input has been provided on the touch panel 13.

An operation button 14 includes the operation buttons 14A through 14Ldescribed above, and operation data is output from the operation button14 to the information processing section 31, the operation dataindicating the states of inputs provided to the respective operationbuttons 14A through 14I (indicating whether or not the operation buttons14A through 14I have been pressed).

The lower LCD 12 and the upper LCD 22 are connected to the informationprocessing section 31. Specifically, the information processing section31 is connected to an LCD controller (not shown) of the upper LCD 22,and causes the LCD controller to set the parallax barrier to on/off.When the parallax barrier is on in the upper LCD 22, the right-eye imageand the left-eye image that are stored in the VRAM 313 of theinformation processing section 31 are output to the upper LCD 22. Morespecifically, the LCD controller repeatedly alternates the reading ofpixel data of the right-eye image for one line in the verticaldirection, and the reading of pixel data of the left-eye image for oneline in the vertical direction, and thereby reads the right-eye imageand the left-eye image from the VRAM 313. Thus, the right-eye image andthe left-eye image are each divided into strip images, each of which hasone line of pixels arranged in the vertical direction, and an imageincluding the divided left-eye strip images and the divided right-eyestrip images alternately arranged is displayed on the screen of theupper LCD 22. The user views the images through the parallax barrier ofthe upper LCD 22, whereby the right-eye image is viewed with the user'sright eye, and the left-eye image is viewed with the user's left eye.This causes the stereoscopically visible image to be displayed on thescreen of the upper LCD 22.

The outer capturing section 23 and the inner capturing section 24 eachcapture an image in accordance with an instruction from the informationprocessing section 31, and output data of the captured image to theinformation processing section 31.

The 3D adjustment switch 25 transmits to the information processingsection 31 an electrical signal in accordance with the position of theslider.

The information processing section 31 controls whether or not the 3Dindicator 26 is to be lit on. When, for example, the upper LCD 22 is inthe stereoscopic display mode, the information processing section 31lights on the 3D indicator 26.

(Overview of Image Processing)

Next, with reference to FIGS. 4 through 72, a description is given of anoverview of image processing performed by the game apparatus 10. Theimage processing performed by the game apparatus 10 includes an imagerecognition process and an image generation process.

The image recognition process is a process of detecting the position ofa marker included in an image captured by a camera (the outer capturingsection (left) 23 a or the outer capturing section (right) 23 b) (acaptured real image). The image generation process is a process ofgenerating an image to be displayed on the upper LCD 22, using theresult of the image recognition process.

Using the result of the image recognition process, the CPU 311 of thegame apparatus 10 can display on the upper LCD 22 an image as if avirtual object actually exists in the vicinity of the marker (e.g., onthe marker) in the real world. For example, in the example of FIG. 4, animage is displayed on the upper LCD 22 of the game apparatus 10, as if avirtual object 60 representing a dog actually exists on a marker 50placed on a table. Such an image is obtained by combining a capturedreal image captured by the camera with an image of the virtual object 60(a virtual space image). The virtual space image is drawn on the basisof a virtual camera placed in a virtual space, and the positionalrelationship between (the relative positions and orientations of) thevirtual object and the virtual camera in the virtual space is controlledin real time so as to coincide with the positional relationship betweenthe camera (the outer capturing section (left) 23 a or the outercapturing section (right) 23 b) and the marker 50 in real space.Consequently, an image is obtained as if the virtual object 60 actuallyexists in real space.

As shown in FIG. 5, the marker 50 is rectangular, and has a white areaalong its periphery and a black area surrounded by the white area.Within the black area, a predetermined internal figure (here, an arrowas an example) is drawn. It should be noted that in the presentembodiment, the marker 50 as shown in FIG. 5 is used; however, this ismerely illustrative. Alternatively, a marker having another shape,another pattern, or another color may be used. For example, the whitearea may be provided within the black area provided along the peripheryof the marker. Yet alternatively, areas of different colors may beprovided instead of the white area and the black area. For a contourdetection process described later, however, the combination of highlycontrasting colors is preferably used.

FIG. 6 is an example of the image captured by the camera (the outercapturing section (left) 23 a or the outer capturing section (right) 23b) (the captured real image). The captured real image includes, forexample, 512 pixels (horizontal direction)×384 pixels (verticaldirection).

To detect the position of the marker 50 from the captured real image asshown in FIG. 6, the following processes are performed in the presentembodiment.

(1) Contour detection process

(2) Vertex detection process

(3) Rough distinction process

(4) Design distinction process

(5) Marker position correction process

(Contour Detection Process)

First, the contour detection process is described. The contour detectionprocess is a process of detecting in the captured real image the contourof a design drawn in the marker 50 (the boundary between the white areaand the black area shown in FIG. 5).

In the present embodiment, in the captured real image, first, the pixelrepresented by the coordinates (16, 16) is defined as a marked pixel.Then, on the basis of the luminance value of the marked pixel and theluminance value of the eighth pixel (8, 16) to the left counting fromthe marked pixel, it is determined whether or not an edge (an edge withthe white area on the left and the black area on the right) is presentanywhere between the two pixels (the determination method will bedescribed in detail later). When it is determined that an edge is notpresent, the eighth pixel (24, 16) to the right counting from thecurrently marked pixel (16, 16) is, as shown in FIG. 7, defined as anewly marked pixel. Then, on the basis of the luminance value of thenewly marked pixel and the luminance value of the eighth pixel to theleft (i.e., the most recently marked pixel (16, 16)) counting from thenewly marked pixel, it is determined whether or not an edge is presentanywhere between the two pixels. Thereafter, similar processes areperformed while sequentially updating the marked pixel. It should benoted that when the processes on the line having a Y-coordinate value of16 are completed, similar processes are performed on the sixteenth linebelow (i.e., the line having a Y-coordinate value of 32) counting fromthe line having a Y-coordinate value of 16. It should be noted that sucha manner of selecting the marked pixel is merely illustrative, and thepresent invention is not limited to this.

In the following descriptions, the marked pixel is represented as apixel P(n); the kth pixel to the left from the marked pixel isrepresented as a pixel P(n−k); and the kth pixel to the right from themarked pixel is represented as a pixel P(n+k). Further, the luminancevalue of the marked pixel is represented as L(n); the luminance value ofthe kth pixel to the left from the marked pixel is represented asL(n−k); and the luminance value of the kth pixel to the right from themarked pixel is represented as L(n+k).

As shown in FIG. 8, the determination of whether or not an edge ispresent anywhere between the marked pixel (i.e., the pixel P(n)) and theeighth pixel to the left (i.e., a pixel P(n−8)) from the marked pixel,is made on the basis of L(n−8) and L(n). Specifically, the determinationis made on the basis of whether or not L(n−8)−L(n) is equal to orgreater than a predetermined value. When L(n−8)−L(n) is equal to orgreater than the predetermined value, it is determined that an edge ispresent somewhere between these pixels. It should be noted that in thepresent embodiment, the luminance value of each pixel is represented bya value of from 0 to 255, and the predetermined value is 60. It shouldbe noted that these numbers are merely illustrative, and the presentinvention is not limited to these.

When it is determined that an edge is present somewhere between thepixel P(n) and the pixel P(n−8), subsequently, an edge determinationthreshold used to detect the position of the edge is calculated on thebasis of the luminance values of these two pixels and pixels near(around) these pixels. With reference to FIGS. 9 through 12, adescription is given below of the calculation method of the edgedetermination threshold.

First, as shown in FIGS. 9 through 12, a white area luminance value Lwis determined on the basis of the luminance values of the pixel P(n−8)and pixels near the pixel P(n−8). A description is given below of anexample of the determination method of the white area luminance valueLw.

First, it is determined whether or not the luminance value of a pixelP(n−9) is smaller than the luminance value of the pixel P(n−8). Ifsmaller, the luminance value of the pixel P(n−8) serves as the whitearea luminance value Lw. For example, in the examples of FIGS. 9, 11,and 12, the luminance value of the pixel P(n−9) is 210, and theluminance value of the pixel P(n−8) is 220. Thus, the luminance value ofthe pixel P(n−8), namely 220, serves as the white area luminance valueLw.

When the luminance value of the pixel P(n−9) is equal to or greater thanthe luminance value of the pixel P(n−8), subsequently, it is determinedwhether or not the luminance value of a pixel P(n−10) is smaller thanthe luminance value of the pixel P(n−9). If smaller, the luminance valueof the pixel P(n−9) serves as the white area luminance value Lw.

When the luminance value of the pixel P(n−9) is equal to or greater thanthe luminance value of the pixel P(n−8), and also the luminance value ofthe pixel P(n−10) is equal to or greater than the luminance value of thepixel P(n−9), subsequently, it is determined whether or not theluminance value of a pixel P(n−11) is smaller than the luminance valueof the pixel P(n−10). If smaller, the luminance value of the pixelP(n−9) serves as the white area luminance value Lw. For example, in theexample of FIG. 10, the luminance value of the pixel P(n−11) is 210, andthe luminance value of the pixel P(n−10) is 220. Thus, the luminancevalue of the pixel P(n−10), namely 220, serves as the white arealuminance value Lw.

The process as described above can be rephrased as a process ofsequentially referring to the luminance values of pixels leftward fromthe pixel P(n−8) and finding a local maximum value of the luminancevalues (the local maximum value that first appears). The process canalso be rephrased as a process of detecting a local maximum value fromamong the luminance values of the pixel P(n−8) and pixels around thepixel P(n−8). Such a process makes it possible that even when, as shownin FIG. 10, the pixel P(n−8) is placed at the boundary between the whitearea and the black area of the marker 50 (is displayed in gray in thecaptured real image), the luminance value of the white area of themarker 50 is correctly set as the white area luminance value Lw.

It should be noted that in the present embodiment, the white arealuminance value Lw is determined as described above; however, this ismerely illustrative, and the determination method of the white arealuminance value Lw is not limited to this. For example, the luminancevalue of the pixel. P(n−8) and the luminance value of any pixel aroundthe pixel P(n−8) may be compared with each other. When the luminancevalue of the pixel around the pixel P(n−8) is greater, the white arealuminance value Lw may be calculated on the basis of the luminance valueof the pixel around the pixel P(n−8). Alternatively, for example, in themiddle of the process of sequentially referring to the luminance valuesof pixels leftward from the pixel P(n−8) and finding a local maximumvalue of the luminance values (the local maximum value that firstappears), when the luminance value of a referred-to pixel has exceeded apredetermined value (e.g., 250), the process of finding a local maximumvalue of the luminance values may be suspended, and the white arealuminance value Lw may be calculated on the basis of the luminance valueof the referred-to pixel.

Next, as shown in FIGS. 9 through 12, a black area luminance value Lb isdetermined on the basis of the luminance values of the pixel P(n) andpixels near the pixel P(n). A description is given below of an exampleof the determination method of the black area luminance value Lb.

First, it is determined whether or not the luminance value of a pixelP(n+2) is equal to or less than the luminance value of the pixel P(n).If equal to or less than the luminance value of the pixel P(n), theluminance value of the pixel P(n) serves as the black area luminancevalue Lb. For example, in the examples of FIGS. 9 and 10, the luminancevalue of the pixel P(n+2) is 100, and the luminance value of the pixelP(n) is 100. Thus, the luminance value of the pixel P(n), namely 100,serves as the black area luminance value Lb.

When the luminance value of the pixel P(n+2) is greater than theluminance value of the pixel P(n), subsequently, it is determinedwhether or not the value obtained by subtracting the luminance value ofthe pixel P(n+2) from the white area luminance value Lw (i.e.,Lw−L(n+2)) is equal to or greater than the predetermined value (i.e.,60). When the obtained value is equal to or greater than 60, theluminance value of the pixel P(n+2) serves as the black area luminancevalue Lb. When the obtained value is less than 60, the luminance valueof the pixel P(n) serves as the black area luminance value Lb.

For example, in the example of FIG. 11, the luminance value of the pixelP(n) is 20; the luminance value of the pixel P(n+2) is 100; and thewhite area luminance value Lw is 220. Then, Lw−L(n+2)=120, andtherefore, the luminance value of the pixel P(n+2), namely 100, servesas the black area luminance value Lb. In a captured real image subjectedto an edge enhancement process (a contour enhancement process or asharpness process), the luminance values of black area pixels adjacentto the white area may occasionally be, as shown in FIG. 11,significantly smaller than intrinsic luminance values of the black area.In response to this, in the present embodiment, the luminance value ofthe pixel P(n+2) serves as the black area luminance value Lb when theconditions as described above are satisfied, so that it is possible todetermine an appropriate black area luminance value Lb even in such acase.

On the other hand, in the example of FIG. 12, the luminance value of thepixel P(n) is 100; the luminance value of the pixel P(n+2) is 210; andthe white area luminance value Lw is 220. Then, Lw−L(n+2)=10, andtherefore, the luminance value of the pixel P(n), namely 100, serves asthe black area luminance value Lb.

It should be noted that in the present embodiment, the black arealuminance value Lb is determined as described above; however, this ismerely illustrative, and the determination method of the black arealuminance value Lb is not limited to this.

When the white area luminance value Lw and the black area luminancevalue Lb have been determined as described above, subsequently, the edgedetermination threshold is calculated on the basis of the white arealuminance value Lw and the black area luminance value Lb. In the presentembodiment, the average value of the white area luminance value Lw andthe black area luminance value Lb is determined as the edgedetermination threshold. For example, in each of the examples of FIGS. 9through 12, the edge determination threshold is 160. This is, however,merely illustrative, and the calculation method of the edgedetermination threshold is not limited to this.

When the edge determination threshold has been determined as describedabove, the position where the edge is present between the pixel P(n) andthe pixel P(n−8) is detected, using the edge determination threshold.Specifically, it is determined that a pixel having a luminance valuegreater than the edge determination threshold is the white area, and itis determined that a pixel having a luminance value smaller than theedge determination threshold is the black area. Then, it is determinedthat the boundary between the white area and the black area is the edge.It should be noted that in the present embodiment, a black area pixeladjacent to the white area is detected as an “edge pixel” placed on theedge (or adjacent to the edge). For example, in the example of FIG. 9,it is determined that a pixel P(n−5) is an edge pixel. In the example ofFIG. 10, it is determined that a pixel P(n−7) is an edge pixel. In theexample of FIG. 11, it is determined that the pixel P(n) is an edgepixel. In the example of FIG. 12, it is determined that a pixel P(n−6)is an edge pixel. It should be noted that in another embodiment, a whitearea pixel adjacent to the black area may be detected as an “edge pixel”placed on the edge.

Each pixel of the captured real image is associated with a flagindicating whether or not the pixel is an edge pixel (an edge flag). Theedge flag of a pixel determined as an edge pixel is set to on.

The edge pixel detected as described above is referred to as a “startingedge pixel” in the following descriptions. The starting edge pixel isestimated as a part of the contour of the design drawn in the marker 50(the boundary between the white area and the black area shown in FIG.5). If the starting edge pixel is a part of the contour of the designdrawn in the marker 50, it is possible to detect the contour of thedesign drawn in the marker 50 (the boundary between the white area andthe black area shown in FIG. 5), by sequentially tracking adjacent edgepixels such that the starting point is the starting edge pixel.

A description is given below of a process of sequentially trackingadjacent edge pixels such that the starting point is the starting edgepixel (an edge tracking process).

First, as shown, in FIG. 13, black area pixels are searched for in theorder of, with the starting edge pixel as a reference, the lower leftadjacent pixel, the lower adjacent pixel, the lower right adjacentpixel, the right adjacent pixel, the upper right adjacent pixel, theupper adjacent pixel, and the upper left adjacent pixel (i.e.,counterclockwise around the starting edge pixel, starting from the leftadjacent pixel). The first detected black area pixel is detected as anew edge pixel subsequent to the starting edge pixel. The determinationof whether or not each adjacent pixel is a black area pixel is made onthe basis of the edge determination threshold used when the startingedge pixel has been detected. More specifically, when the luminancevalue of an adjacent pixel is smaller than the edge determinationthreshold, it is determined that the adjacent pixel is a black areapixel.

For example, in the example of FIG. 14, the lower left adjacent pixel isdetected as a new edge pixel. In the example of FIG. 15, the rightadjacent pixel is detected as a new edge pixel.

When, in the edge tracking process, edge pixels have been sequentiallydetected such that the starting point is the starting edge pixel, thecoordinate values of the detected edge pixels are sequentially stored inthe main memory 32 as a series of edge pixels. It should be noted thatin the following descriptions, the edge pixel last detected in the edgetracking process is referred to as a “front edge pixel”, and the edgepixel detected immediately before the front edge pixel is referred to asa “second edge pixel”.

A new edge pixel subsequent to the front edge pixel is detected bysearching for a black area pixel counterclockwise around the front edgepixel, such that the starting point is the adjacent pixel placed in thedirection shifted 135 degrees counterclockwise from the direction of thesecond edge pixel as viewed from the front edge pixel (in anotherembodiment, the starting point may be the adjacent pixel placed in thedirection shifted 45 degrees counterclockwise, or may be the adjacentpixel placed in the direction shifted 90 degrees counterclockwise).Then, the black area pixel first detected in the search is detected as anew edge pixel (i.e., a new front edge pixel).

For example, as shown in FIG. 16, when the second edge pixel is theupper right adjacent pixel to the front edge pixel, a black area pixelis searched for counterclockwise around the front edge pixel, startingfrom the left adjacent pixel. Accordingly, in the example of FIG. 17,the lower adjacent pixel to the front edge pixel is detected as a newedge pixel.

In addition, for example, as shown in FIG. 18, when the second edgepixel is the left adjacent pixel to the front edge pixel, a black areapixel is searched for counterclockwise around the front edge pixel,starting from the lower right adjacent pixel. Accordingly, in theexample of FIG. 19, the right adjacent pixel to the front edge pixel isdetected as a new edge pixel.

New edge pixels are sequentially detected by repeating the process asdescribed above. Then, ultimately, the front edge pixel reaches thestarting edge pixel, whereby the detection of the contour of the blackarea is completed (i.e., data concerning a series of an edge pixel groupindicating the contour of the black area is stored in the main memory32).

It should be noted that in the present embodiment, each time a new edgepixel is detected in the edge tracking process, it is determined, on thebasis of the edge flag, whether or not the new edge pixel is included inthe series of an edge pixel group that has already been detected. Whenit is determined three consecutive times that the new edge pixel isincluded in the series of an edge pixel group that has already beendetected, the edge tracking process is suspended.

For example, as shown in FIG. 20, when it is determined only twoconsecutive times that the new edge pixel is included in the series ofan edge pixel group that has already been detected, the edge trackingprocess is not suspended.

As shown in FIG. 21, however, when it is determined three consecutivetimes that the new edge pixel is included in the series of an edge pixelgroup that has already been detected, the edge tracking process issuspended. This is because there is a high possibility that the blackarea as shown in FIG. 21 is not the contour of the design drawn in themarker 50 (i.e., is the contour of an object other than the marker 50).Further, even if the black area is the contour of the design drawn inthe marker 50, it is highly unlikely to be able to normally perform apattern matching process described later and the like. This makes itpossible to avoid unnecessary processes. It should be noted that thenumber of times, namely three times, is merely illustrative, and may beanother number of times.

It should be noted that in the above description, as an example, thecontour of the black area is tracked counterclockwise such that thestarting point is the starting edge pixel. Alternatively, in anotherembodiment, the contour of the black area may be tracked clockwise suchthat the starting point is the starting edge pixel.

As described above, in the contour detection process, the white arealuminance value Lw and the black area luminance value Lb are determined,and the edge determination threshold is calculated on the basis of thewhite area luminance value Lw and the black area luminance value Lb.Accordingly, even when the brightness of a captured real image hasentirely or partially changed, and the luminances of the white area andthe black area of the marker 50 in the captured real image have changedin accordance with the change, it is possible to perform the contourdetection process using an appropriate edge determination threshold.This improves the accuracy of recognizing the marker 50.

It should be noted that in the contour detection process, the contour isextracted on the basis of the luminance values of pixels; however, thepresent invention is not limited to luminance values. Alternatively, thecontour may be detected on the basis of other given pixel values(typically, color values).

In addition, in the contour detection process, first, it is determinedwhether or not an edge is present between two pixels separate in thehorizontal direction (the pixel P(n) and the pixel P(n−8)); however, themanner of selecting two pixels is not limited to this. For example, itmay be determined whether or not an edge is present between two pixelsseparate in the vertical direction. Alternatively, it may be determinedwhether or not an edge is present between two pixels separate in adiagonal direction.

In addition, in the contour detection process, when L(n−8)−L(n) is equalto or greater than a predetermined value, it is determined that an edgeis present between the pixel P(n) and the pixel P(n−8) (in this case, itis possible to find an edge with the white area on the left and theblack area on the right). Alternatively, in another embodiment, when theabsolute value of L(n−8)−L(n) is equal to or greater than apredetermined value, it may be determined that an edge is presentbetween the pixel P(n) and the pixel P(n−8). In this case, it ispossible to find not only an edge with the white area on the left andthe black area on the right, but also an edge with the black area on theleft and the white area on the right.

In addition, in the contour detection process, the edge determinationthreshold used when the starting edge pixel has been detected is used inthe edge tracking process. Alternatively, in another embodiment, theedge determination threshold may be used to detect an edge pixel from agiven area in the captured real image (e.g., the entire captured realimage). For example, the following may be detected on the basis of theedge determination threshold: an edge pixel on the line placed one linelower than the line including the starting edge pixel; and an edge pixelof a contour other than the contour including the starting edge pixel.

(Vertex Detection Process)

Next, the vertex detection process is described. The vertex detectionprocess is a process of detecting the four vertices of the black area ofthe marker 50 in the captured real image, and includes the followingprocesses.

Straight line calculation process

Straight line integration process

Straight line selection process

Vertex calculation process

In the straight line calculation process, a plurality of straight linesare calculated on the basis of the data concerning the series of an edgepixel group indicating the contour of the black area, the data stored inthe main memory 32 in the contour detection process described above.With reference to FIGS. 22 through 36, the straight line calculationprocess is described in detail below.

In the data concerning the series of an edge pixel group stored in themain memory 32, a plurality of edge pixels are ordered. In the followingdescriptions, for convenience, the direction of tracking the contour ofthe black area counterclockwise (i.e., the left direction as viewed fromthe black area in the direction of the white area) is defined asforward, and the direction of tracking the contour of the black areaclockwise (i.e., the right direction as viewed from the black area inthe direction of the white area) is defined as backward.

First, as shown in FIG. 22, a first straight line Li(0-4) is generatedon the basis of five edge pixels Pe(0) through Pe(4), starting from thestarting edge pixel Pe(0) to the edge pixel Pe (4), which is four pixelsahead of the starting edge pixel Pe(0), and data indicating the straightline Li(0-4) is stored in the main memory 32. It should be noted that itis possible to employ various methods as a method of generating astraight line on the basis of a plurality of edge pixels. In the presentembodiment, a straight line is generated by a least squares method.

Next, as shown in FIG. 23, a provisional straight line is generated by,for example, a least squares method on the basis of five edge pixelsPe(5) through Pe(9) immediately ahead of the straight line Li(0-4), andit is determined whether or not the straight line Li(0-4) and theprovisional straight line are placed on the same straight line. Thedetermination is made on the basis of, for example, the angle of theprovisional straight line with respect to the straight line Li(0-4). Inthe present embodiment, as shown in FIG. 24, when the angle of theprovisional straight line with respect to the straight line Li(0-4) (onthe assumption that the counterclockwise direction is positive) is inthe range from −30° to +30°, it is determined that the straight lineLi(0-4) and the provisional straight line are placed on the samestraight line. It should be noted that the values such as −30° and +30°are merely illustrative, and the present invention is not limited tothese.

When it is determined that the straight line Li(0-4) and the provisionalstraight line are placed on the same straight line, a straight lineLi(0-9) is calculated as shown in FIG. 25 by, for example, a leastsquares method on the basis of 10 edge pixels, namely the edge pixelsPe(0) through Pe(4) corresponding to the straight line Li(0-4) and theedge pixels Pe(5) through Pe(9) corresponding to the provisionalstraight line, and the data indicating the straight line Li(0-4) storedin the main memory 32 is updated to data indicating the straight lineLi(0-9). Such a process is repeated, whereby the straight line issequentially updated (extended). It should be noted that in the presentembodiment, a provisional straight line is generated every five edgepixels; however, this is merely illustrative, and the present inventionis not limited to this.

In the example of FIG. 26, the angle of a provisional straight line(i.e., a provisional straight line generated on the basis of five edgepixels Pe(15) through Pe(19) ahead of a straight line Li(0-14)) withrespect to the straight line Li(0-14) exceeds +30°, and therefore, it isdetermined that the black area has a convex angle near the intersectionof the straight line Li(0-14) and the provisional straight line (i.e.,the black area is pointed outward near the intersection of the straightline Li(0-14) and the provisional straight line) (see FIG. 24). In thiscase, it is determined that the provisional straight line is a newstraight line different from the straight line Li(0-14). Then, a newstraight line Li(15-19) corresponding to the provisional straight lineis generated (see FIG. 27). In this case, data indicating the straightline Li(0-14) is held as it is in the main memory 32, and dataindicating the straight line Li(15-19) is newly stored in the mainmemory 32.

Subsequently, as shown in FIG. 28, it is determined whether or not thestraight line Li(15-19) and a provisional straight line generated on thebasis of five edge pixels Pe(20) through Pe(24) ahead of the straightline Li(15-19) are placed on the same straight line. When it isdetermined that these lines are placed on the same straight line, thestraight line Li(15-19) is updated to a straight line Li(15-24) on thebasis of the edge pixels Pe(15) through Pe(24), as shown in FIG. 29.

The process as described above is repeated, whereby a plurality ofstraight lines are ultimately calculated as shown in FIG. 30 (sixstraight lines, namely straight lines A through F, in the example ofFIG. 30). It should be noted that these lines may include a shortstraight line, such as the straight line D.

As described above, in the straight line calculation process, eachstraight line is calculated from, among a series of edge pixels, someedge pixels placed on the same straight line.

It should be noted that in the straight line calculation process, astraight line is generated or updated such that the starting point isthe starting edge pixel Pe(0); however, the present invention is notlimited to this. Alternatively, a straight line may be generated orupdated such that a given edge pixel other than the starting point isthe starting edge pixel Pe(0).

In addition, in the straight line calculation process, a straight lineis generated or updated counterclockwise; however, the present inventionis not limited to this. Alternatively, a straight line may be generatedor updated clockwise.

In addition, in the straight line calculation process, it is determinedwhether or not an already generated straight line and a provisionalstraight line adjacent thereto are placed on the same straight line, andwhen it is determined that these lines are placed on the same straightline, a straight line is calculated on the basis of a plurality of edgepixels corresponding to the straight line and the provisional straightline. Alternatively, in another embodiment, after numerous provisionalstraight lines are generated first, a straight line may be calculated onthe basis of a plurality of edge pixels corresponding to, among thenumerous provisional straight lines, a plurality of provisional straightlines placed on the same straight line.

The case is considered where, as shown in FIG. 31, a black object isdisplayed so as to partially overlap a side of the black area of themarker 50 in the captured real image. In this case, in the straight linecalculation process, after a straight line A and a straight line B havebeen generated, it is determined, as shown in FIG. 32, whether or notthe straight line B and a provisional straight line ahead of thestraight line B are placed on the same straight line. The angle of theprovisional straight line with respect to the straight line B is smallerthan −30°, and therefore, it is determined that the black area has aconcave angle near the intersection of the straight line B and theprovisional straight line (i.e., the black area is depressed inward nearthe intersection of the straight line B and the provisional straightline) (see FIG. 24). There is no concave angle in the contour of theblack area of the marker 50 (i.e., there are only convex angles), andtherefore, when such a concave angle has been detected, it is estimatedthat the provisional straight line indicates a part of the contour of anobject other than the marker.

As described above, when a concave angle has been detected in thestraight line calculation process, it is determined that it is notpossible to perform a process of updating (extending) or newlygenerating a straight line. Then, the process is suspended of updating(extending) or newly generating a straight line counterclockwise in theblack area, and a process is started of updating (extending) or newlygenerating a straight line in the direction opposite to the previousdirection (i.e., clockwise). For example, in the example of FIG. 31, aprocess is performed of extending backward the straight line A,clockwise from the starting edge pixel, and also a process is performedof generating a new straight line. As a result, as shown in FIG. 33, thestraight line A shown in FIG. 31 is updated to a straight line A′, andstraight lines C through E are sequentially generated. It should benoted that a concave angle is detected at the rear end of the straightline E, and therefore, the straight line calculation process ends at thetime of the detection. As a result, five straight lines, namely thestraight line A′ and the straight lines B through E, are calculated.

As yet another example, as shown in FIG. 34, the case is consideredwhere a white object is displayed so as to partially overlap a side ofthe black area of the marker 50 in the captured real image. In thiscase, in the straight line calculation process, after straight lines Athrough C have been generated, a concave angle is detected. Then, aprocess is started of extending backward the straight line A, clockwisefrom the starting edge pixel, and also a process is started ofgenerating a new straight line. The straight line A is updated to astraight line A′, and straight lines D through G are sequentiallygenerated. As a result, seven straight lines, namely the straight lineA′ and the straight lines B through G, are calculated.

As yet another example, the ease is considered where, as shown in FIG.35, a black object is displayed so as to overlap a vertex of the blackarea of the marker 50 in the captured real image. In this case, as aresult, four straight lines, namely, a straight line A′ and straightlines B through D, are calculated.

As yet another example, the case is considered where, as shown in FIG.36, a white object is displayed so as to overlap a vertex of the blackarea of the marker 50 in the captured real image. In this case, as aresult, six straight lines, namely a straight line A′ and straight linesB through F, are calculated.

When the straight line calculation process is completed, the straightline integration process is subsequently performed. The straight lineintegration process is a process of integrating, among a plurality ofstraight lines calculated in the straight line calculation process, aplurality of straight lines placed on the same straight line anddirected in the same direction into one straight line.

For example, in the example of FIG. 30, the straight line A and thestraight line F are placed on the same straight line and directed in thesame direction, and therefore, as shown in FIG. 37, these two straightlines are integrated into one straight line A+F.

In addition, for example, in the example of FIG. 33, the straight line Band the straight line E are placed on the same straight line anddirected in the same direction, and therefore, as shown in FIG. 38,these two straight lines are integrated into one straight line B+E.

In addition, for example, in the example of FIG. 34, the straight line Band the straight line F are placed on the same straight line anddirected in the same direction, and therefore, as shown in FIG. 39,these two straight lines are integrated into one straight line B+F.

When the straight line integration process is completed, the straightline selection process is subsequently performed. The straight lineselection process is a process of selecting straight lines correspondingto the four sides of the black area of the marker 50, from among theplurality of straight lines finally remaining after the straight linecalculation process and the straight line integration process.

In the present embodiment, the four longest straight lines (i.e., thelongest straight line, the second longest straight line, the thirdlongest straight line, and the fourth longest straight line) areselected as straight lines corresponding to the four sides of the blackarea of the marker 50, from among the plurality of finally remainingstraight lines. In the following descriptions, the selected fourstraight lines are referred to as a “first straight line”, a “secondstraight line”, a “third straight line”, and a “fourth straight line”,counterclockwise from a given straight line among these lines.

For example, in the example of FIG. 37, the straight line A+F, thestraight line B, the straight line C, and the straight line E areselected from among five straight lines, namely the straight line A+Fand the straight lines B through E, in the straight line selectionprocess (see FIG. 40).

In addition, for example, in the example of FIG. 39, the straight lineA′, the straight line B+F, the straight line E, and the straight line Dare selected from among six straight lines, namely the straight line A′,the straight line B+F, the straight lines C through E, and the straightline G, in the straight line selection process.

In addition, for example, in the example of FIG. 36, the straight lineA′, the straight line B, the straight line E, and the straight line Dare selected from among six straight lines, namely the straight line A′and the straight lines B through F, in the straight line selectionprocess (see FIG. 41).

It should be noted that in the examples of FIGS. 35 and 38, only fourstraight lines are present, and therefore, these four straight lines areselected in the straight line selection process.

It should be noted that in the straight line selection process, fourstraight lines are selected because the black area of the marker 50 isrectangular. Accordingly, if the black area of the marker 50 is, forexample, hexagonal, six straight lines are selected in the straight lineselection process.

When the straight line selection process is completed, the vertexcalculation process is subsequently performed. In the vertex calculationprocess, the positions of the four vertices of the black area of themarker 50 are calculated on the basis of the four straight lines (firstthrough fourth straight lines) selected in the straight line selectionprocess.

Specifically, the position of the intersection of the first straightline and the second straight line is calculated as the position of afirst vertex of the black area of the marker 50. The position of theintersection of the second straight line and the third straight line iscalculated as the position of a second vertex of the black area of themarker 50. The position of the intersection of the third straight lineand the fourth straight line is calculated as the position of a thirdvertex of the black area of the marker 50. The position of theintersection of the fourth straight line and the first straight line iscalculated as the position of a fourth vertex of the black area of themarker 50.

For example, in the example of FIG. 40, the positions of the firstthrough fourth vertices are calculated as shown in FIG. 42. Further, forexample, in the example of FIG. 41, the positions of the first throughfourth vertices are calculated as shown in FIG. 43.

As described above, the four vertices of the black area of the marker 50in the captured real image are detected through the straight linecalculation process, the straight line integration process, the straightline selection process, and the vertex calculation process.

The positions of the vertices thus detected are calculated as theintersections of straight lines generated on the basis of a plurality ofedge pixels placed on the same straight line, and therefore have highaccuracy. For example, when any one of a series of edge pixels isdetermined as a vertex, the position of the vertex deviates due, forexample, to the effect of environmental light. The position of a vertexdetected as described above, however, is calculated on the basis ofnumerous edge pixels, and therefore, such a deviation does not occur.

(Rough Distinction Process)

Next, the rough distinction process is described. The rough distinctionprocess is a process of, prior to the design distinction processdescribed later, determining whether or not the four vertices detectedin the vertex detection process are the four vertices of the marker 50,on the basis of the positional relationships between the four vertices.

In the present embodiment, when exclusion conditions A through D shownbelow have been satisfied, it is determined that the four verticesdetected in the vertex detection process are not the four vertices ofthe marker 50.

(Exclusion Condition A) the Case where the Distance Between any TwoAdjacent Vertices is Too Small

Specifically, the case is: where the distance between the first vertexand the second vertex is smaller than a predetermined threshold (a firstminimum acceptable distance); where the distance between the secondvertex and the third vertex is smaller than the first minimum acceptabledistance; where the distance between the third vertex and the fourthvertex is smaller than the first minimum acceptable distance; or wherethe distance between the fourth vertex and the first vertex is smallerthan the first minimum acceptable distance. For example, in the exampleof FIG. 44, the distance between the first vertex and the second vertexis too small, and therefore, it is determined that the first throughfourth vertices are not the four vertices of the marker 50.

(Exclusion Condition B) the Case where the Distance Between any Vertexand Either One of the Two Sides not Adjacent to the Vertex is Too Small

Specifically, the case is: where the distance between the first vertexand the third straight line is smaller than a predetermined threshold (asecond minimum acceptable distance); where the distance between thefirst vertex and the fourth straight line is smaller than the secondminimum acceptable distance; where the distance between the secondvertex and the fourth straight line is smaller than the second minimumacceptable distance; where the distance between the second vertex andthe first straight line is smaller than the second minimum acceptabledistance; where the distance between the third vertex and the firststraight line is smaller than the second minimum acceptable distance;where the distance between the third vertex and the second straight lineis smaller than the second minimum acceptable distance; where thedistance between the fourth vertex and the second straight line issmaller than the second minimum acceptable distance; or where thedistance between the fourth vertex and the third straight line issmaller than the second minimum acceptable distance. For example, in theexample of FIG. 45, the distance between the first vertex and the thirdstraight line is too small, and therefore, it is determined that thefirst through fourth vertices are not the four vertices of the marker50.

(Exclusion Condition C) The Case where the Straight Lines (Vectors) ofany Two Opposing Sides are Directed in Generally the Same Direction

Specifically, the case is: where the first straight line (the vectorconnecting the fourth vertex to the first vertex) and the third straightline (the vector connecting the second vertex to the third vertex) aredirected in generally the same direction; or where the second straightline (the vector connecting the first vertex to the second vertex) andthe fourth straight line (the vector connecting the fourth vertex to thefirst vertex) are directed in generally the same direction. For example,in the example of FIG. 46, the first straight line (the vectorconnecting the fourth vertex to the first vertex) and the third straightline (the vector connecting the second vertex to the third vertex) aredirected in generally the same direction, and therefore, it isdetermined that the first through fourth vertices are not the fourvertices of the marker 50. It should be noted that it is possible todetermine whether or not two vectors are directed in generally the samedirection, on the basis of the angle between the two vectors, forexample, as shown in FIG. 24.

(Exclusion Condition D) The Case where a Concave Angle is Included

Specifically, the case is where any one of the first through fourthvertices has a concave angle. For example, in the example of FIG. 47,the second vertex has a concave angle, and therefore, it is determinedthat the first through fourth vertices are not the four vertices of themarker 50.

It should be noted that in the present embodiment, the rough distinctionprocess is performed on the basis of the exclusion conditions A throughD; however, this is merely illustrative. Alternatively, one or more ofthe exclusion conditions may be used, or an exclusion conditiondifferent from these exclusion conditions may be used.

When any of the exclusion conditions A through D are satisfied, it isdetermined that the four vertices detected in the vertex detectionprocess are not the four vertices of the marker 50, and the detectedfour vertices are excluded from process objects in the designdistinction process described later. This reduces processing loadrequired in the design distinction process.

(Design Distinction Process)

Next, the design distinction process is described. The designdistinction process is a process of determining whether or not thedesign displayed in the area surrounded by the four vertices detected inthe vertex detection process is the same as the design drawn in themarker 50.

In the design distinction process, it is determined, using patterndefinition data generated in advance on the basis of the design drawn inthe marker 50, whether or not the design displayed in the areasurrounded by the four vertices detected in the vertex detection processis the same as the design drawn in the marker 50.

The pattern definition data is data representing the design drawn in themarker 50, and, in the present embodiment, is data in which, as shown inFIG. 48, the intersections of the grid generated by dividing each sideof the marker 50 into 16 equal parts are used as sample points (S(1, 1)through S(15, 15)), and the pixel values of the sample points in themarker 50 are defined (see FIG. 49). It should be noted that in thepresent embodiment, each side of the marker 50 is divided into 16 parts;however, this is merely illustrative. The present invention is notlimited to division into 16 parts. Further, in the present embodiment,the intersections of the grid generated by dividing each side of themarker 50 into equal parts are used as the sample points. Alternatively,in another embodiment, the centers of the rectangles separated by thegrid may be used as the sample points.

In the present embodiment, the intersection closest to the upper leftvertex of the marker 50 is the sample point S(1, 1); the intersectionclosest to the lower left vertex of the marker 50 is the sample pointS(1, 15); the intersection closest to the upper right vertex of themarker 50 is the sample point S(15, 1); and the intersection closest tothe lower right vertex of the marker 50 is the sample point S(15, 15).

It should be noted that in the example of FIG. 49, the pixel values aredefined as “black” or “white” in the columns of the pixel values.Alternatively, in another embodiment, the pixel values may be definedas, for example, color values (RGB value) and luminance values.

FIG. 50 shows a captured real image including the marker 50. Thepositions of the first through fourth vertices are calculated byperforming the contour detection process and the vertex detectionprocess that are described above on the captured real image.

FIG. 51 shows an example where, in the captured real image, each side ofthe rectangle surrounded by the first through fourth vertices is dividedinto 16 equal parts, whereby the positions of the sample points includedin the area surrounded by these vertices are determined.

In the design distinction process, the pixel values of the sample pointsin the captured real image are checked against the pattern definitiondata (e.g., correlation coefficients are calculated), whereby it isdetermined whether or not the design displayed in the area surrounded bythe first through fourth vertices in the captured real image is the sameas the design drawn in the marker 50. However, when the sample points inthe captured real image are determined by a method as shown in FIG. 51,it may not be possible to make accurate determinations. For example, thepixel value of the sample point S(8, 2) in the pattern definition datais “black”, whereas the pixel value of the sample point S(8, 2) in thecaptured real image shown in FIG. 51 is “white”. Further, the pixelvalue of the sample point S(8, 13) in the pattern definition data is“white”, whereas the pixel value of the sample point S(8, 13) in thecaptured real image shown in FIG. 51 is “black”. As a result, it may beerroneously determined that the marker 50 is not included in thecaptured real image shown in FIG. 50.

To solve the above problem, it is necessary to devise the determinationmethod of the positions of the sample points in the captured real image.A description is given below of another example of the determinationmethod of the positions of the sample points in the captured real image(a first determination method and a second determination method).

First, with reference to FIGS. 52 through 58, a description is given ofthe first determination method of determining the positions of thesample points in the captured real image.

In the first determination method, in the rectangle surrounded by thefirst through fourth vertices: when two opposing sides are parallel(including the case where they are generally parallel) to each other,the two sides are each divided into 16 equal parts; and when twoopposing sides are not parallel to each other, the two sides are eachdivided into 16 unequal parts. The intersections of the grid thusgenerated are used as the sample points.

For example, in the example of FIG. 52, the side connecting the firstvertex to the fourth vertex and the side connecting the second vertex tothe third vertex are parallel to each other, and therefore, the sideconnecting the first vertex to the fourth vertex and the side connectingthe second vertex to the third vertex are each divided into 16 equalparts. On the other hand, the side connecting the first vertex to thesecond vertex and the side connecting the fourth vertex to the thirdvertex are not parallel to each other, and therefore, the sideconnecting the first vertex to the second vertex and the side connectingthe fourth vertex to the third vertex are not each divided into 16 equalparts, but are each divided into 16 unequal parts. That is, as shown inFIG. 52, the points dividing the side connecting the first vertex to thesecond vertex into 16 parts (hereinafter referred to as “divisionpoints”) are shifted to the first vertex side, as compared to the casewhere the same side is divided into 16 equal parts. Further, thedivision points dividing the side connecting the fourth vertex to thethird vertex into 16 parts are shifted to the fourth vertex side, ascompared to the case where the same side is divided into 16 equal parts.

With reference to FIGS. 53 through 55, a description is given below ofan example of the determination method of the division points on theside connecting the first vertex to the second vertex, and the divisionpoints on the side connecting the fourth vertex to the third vertex, inFIG. 52.

It should be noted that in the following descriptions, the 15 divisionpoints dividing the side connecting the first vertex to the secondvertex into 16 parts are referred to as a “first division point M1”, a“second division point M2”, a “third division point M3” . . . , and a“fifteenth division point M15”, in the order from the point closer tothe first vertex. Similarly, the 15 division points dividing the sideconnecting the fourth vertex to the third vertex into 16 parts arereferred to as a “first division point N1”, a “second division pointN2”, a “third division point N3” . . . , and a “fifteenth division pointN15”, in the order from the point closer to the fourth vertex.

First, as shown in FIG. 53, the eighth division point M8 and the eighthdivision point N8 are determined. Specifically, first, the distancebetween the first vertex and the fourth vertex and the distance betweenthe second vertex and the third vertex are calculated. Then, when thedistance between the first vertex and the fourth vertex is a and thedistance between the second vertex and the third vertex is b, the pointdividing, in a ratio of a:b, the straight line connecting the firstvertex to the second vertex, and the point dividing, in a ratio of a:b,the straight line connecting the fourth vertex to the third vertex arecalculated. Then, the first calculated point is determined as the eighthdivision point M8, and the second calculated point is determined as theeighth division point N8. As a result, the eighth division point M8 isdetermined at a position closer to the first vertex than the midpoint ofthe first vertex and the second vertex is. The eighth division point N8is determined at a position closer to the fourth vertex than themidpoint of the fourth vertex and the third vertex is.

Next, as shown in FIG. 54, the fourth division point M4 and the fourthdivision point N4 are determined. Specifically, first, the distancebetween the eighth division point M8 and the eighth division point N8 iscalculated. Then, when the calculated distance is c, the point dividing,in a ratio of a:e, the straight line connecting the first vertex to theeighth division point M8, and the point dividing, in a ratio of a:c, thestraight line connecting the fourth vertex to the eighth division pointN8 are calculated. Then, the first calculated point is determined as thefourth division point M4, and the second calculated point is determinedas the fourth division point N4. As a result, the fourth division pointM4 is determined at a position closer to the first vertex than themidpoint of the first vertex and the eighth division point M8 is. Thefourth division point N4 is determined at a position closer to thefourth vertex than the midpoint of the fourth vertex and the eighthdivision point N8 is.

Next, as shown in FIG. 55, the second division point M2 and the seconddivision point N2 are determined. Specifically, first, the distancebetween the fourth division point M4 and the fourth division point N4 iscalculated. Then, when the calculated distance is d, the point dividing,in a ratio of a:d, the straight line connecting the first vertex to thefourth division point M4, and the point dividing, in a ratio of a:d, thestraight line connecting the fourth vertex to the fourth division pointN4 are calculated. Then, the first calculated point is determined as thesecond division point M2, and the second calculated point is determinedas the second division point N2. As a result, the second division pointM2 is determined at a position closer to the first vertex than themidpoint of the first vertex and the fourth division point M4 is. Thesecond division point N2 is determined at a position closer to thefourth vertex than the midpoint of the fourth vertex and the fourthdivision point N4 is.

Subsequently, similarly, the remaining division points (the firstdivision point M1, the third division point M3, the firth division pointMS through the seventh division point M7, the ninth division point M9through the fifteenth division point M15, the first division point N1,the third division point N3, the fifth division point N5 through theseventh division point N7, and the ninth division point N9 through thefifteenth division point N15) are determined, and the sample points asshown in FIG. 52 are ultimately determined.

It should be noted that in the first determination method, when twoopposing sides of the rectangle surrounded by the first through fourthvertices are parallel to each other, the two sides are divided into 16equal parts. With reference to FIGS. 56 through 58, the reason for thisis explained below.

When the first through fourth vertices as shown in FIG. 56 have beendetected in the captured real image, the side connecting the firstvertex to the fourth vertex and the side connecting the second vertex tothe third vertex are parallel to each other. In such a case, if thesesides are divided into 16 parts using the method shown in FIGS. 53through 55, the division points dividing the side connecting the firstvertex to the fourth vertex are placed closer to the first vertex as awhole, and the division points dividing the side connecting the secondvertex to the third vertex are placed closer to the second vertex as awhole, as shown in FIG. 57.

However, when in the captured real image, the marker 50 is displayed inthe shape as shown in FIG. 56 (i.e., when the side connecting the firstvertex to the fourth vertex and the side connecting the second vertex tothe third vertex are parallel to each other), the distance between thecamera and the first vertex and the distance between the camera and thefourth vertex are almost the same. Similarly, the distance between thecamera and the second vertex and the distance between the camera and thethird vertex are almost the same. Accordingly, in such a case, as shownin FIG. 58, the division of the side connecting the first vertex to thefourth vertex into 16 equal parts, and the division of the sideconnecting the second vertex to the third vertex into 16 equal parts,make it possible to determine the positions of the sample points at moreappropriate positions.

Next, with reference to FIGS. 59 and 60, a description is given of thesecond determination method of determining the positions of the samplepoints in the captured real image.

In the second determination method, as shown in FIG. 59, first, pairs oftwo opposing sides of the rectangle surrounded by the four verticesdetected in the vertex detection process are extended, and theintersections of the respective pairs of two opposing sides (a firstvanishing point and a second vanishing point) are calculated. In thefollowing descriptions, among the four vertices detected in the vertexdetection process, the vertex closest to the straight line connectingthe first vanishing point to the second vanishing point (a firststraight line) is referred to as a “vertex A”, and the remainingvertices are referred to as a “vertex B”, a “vertex C”, and a “vertexD”, counterclockwise from the vertex A.

Next, a straight line passing through the vertex C and parallel to thestraight line (first straight line) connecting the first vanishing pointto the second vanishing point (a second straight line) is calculated.Then, the intersection of a straight line passing through the vertices Aand B and the second straight line (a first point), and the intersectionof a straight line passing through the vertices A and D and the secondstraight line (a second point) are calculated.

Next, as shown in FIG. 60, 15 division points dividing the straight lineconnecting the first point to the vertex C into 16 equal parts arecalculated, and the calculated division points are connected to thesecond vanishing point. Similarly, 15 division points dividing thestraight line connecting the vertex C to the second point into 16 equalparts are calculated, and the calculated division points are connectedto the first vanishing point. The intersections thus generated aredetermined as the sample points in the captured real image.

According to the result of verification carried out by the presentinventor, it has been confirmed that the employment of the seconddetermination method makes it possible to determine the sample points inthe captured real image more appropriately than the first determinationmethod. Even the first determination method, however, has a greatadvantage over the method shown in FIG. 51, and therefore, a designermay appropriately determine whether to employ the first determinationmethod or the second determination method, taking into accountconditions, such as a required detection accuracy and the complexity ofthe design of the marker 50.

As in the first determination method and the second determinationmethod, the sample points in the captured real image are determined bydividing each side of at least one pair of two opposing sides intounequal parts, whereby it is possible to distinguish the marker 50 moreaccurately than the method shown in FIG. 51.

It should be noted that the method of dividing each side of two opposingsides into unequal parts is not limited to the first determinationmethod and the second determination method, and another method may beemployed.

It should be noted that, immediately after the vertex detection process,it is not possible to determine which vertex among the first throughfourth vertices detected in the vertex detection process corresponds towhich vertex among the upper left vertex, the lower left vertex, thelower right vertex, and the upper right vertex of the marker 50.Accordingly, there are the following four possible cases: where thefirst vertex corresponds to the upper left vertex; where the firstvertex corresponds to the lower left vertex; where the first vertexcorresponds to the lower right vertex; and where the first vertexcorresponds to the upper right vertex. Thus, in the design distinctionprocess, the pixel values of the sample points in the captured realimage in each of these four cases are checked against the patterndefinition data. As a result, in the captured real image, thecoordinates of the upper left vertex, the coordinates of the lower leftvertex, the coordinates of the lower right vertex, and the coordinatesof the upper right vertex are detected, and the detected coordinates arestored in the main memory 32 as marker position information.

In the game apparatus 10, on the basis of captured real imagessequentially acquired in real time from the camera, the contourdetection process, the vertex detection process, the rough distinctionprocess, and the design distinction process are performed in apredetermined cycle (e.g., in a cycle of 1/60 seconds) and repeated.This makes it possible to detect in real time the position of the marker50 in the captured real image.

However, due, for example, to the manner of the application of light tothe marker 50, even though the marker 50 is displayed in the capturedreal image, the detection of the contour and the vertices of the marker50 in the captured real image may temporarily fail. When the detectionof the contour and the vertices of the marker 50 has temporarily failed,for example, in the state shown in FIG. 4, the virtual object 60temporarily disappears even though the user has not moved the gameapparatus 10. If the virtual object 60 frequently disappears andappears, the user's interest is dampened.

In the present embodiment, to prevent such an unfavorable phenomenon (anunintended change in the position of the marker), when the detection ofthe contour and the vertices of the marker 50 has failed in the currentcaptured real image, the design distinction process is performed on thecurrent captured real image on the basis of the positions of thevertices (or the sample points) of the marker 50 detected from the mostrecent captured real image. It should be noted that the “currentcaptured real image” means the captured real image that is currentlybeing processed, and does not necessarily mean the latest captured realimage captured by the camera.

Specifically, when the detection of the contour and the vertices of themarker 50 has failed in the current captured real image, the positionsof the four vertices of the marker 50 detected from the most recentcaptured real image (or the sample points determined on the basis of thefour vertices) are, as shown in FIG. 61, acquired from the markerposition information stored in the main memory 32. Then, as shown in.FIG. 62, on the basis of the positions of the four vertices of themarker 50 detected from the most recent captured real image, thepositions of the sample points in the current captured real image aredetermined, and the design distinction process is performed using thepixel values of the sample points thus determined (or the sample pointsdetermined in the previous design distinction process). As a result ofthe design distinction process, when it is determined that in thecurrent captured real image, the marker 50 is present at the sameposition as that in the most recent captured real image, the coordinatesof the four vertices of the marker 50 in the most recent captured realimage are stored in the main memory 32 as marker position informationcorresponding to the current captured real image.

By the process as described above, in the case where the user has notmoved the game apparatus 10, even if the detection of the contour andthe vertices of the marker 50 in the captured real image has temporarilyfailed, it is possible to detect the position of the marker 50.Accordingly, as described above, it is possible to prevent the virtualobject 60 from frequently disappearing and appearing even though theuser has not moved the game apparatus 10.

It should be noted that the position of the marker 50 in the currentcaptured real image may be slightly shifted from the position of themarker 50 in the most recent captured real image. In response, inanother embodiment, the design distinction process may be performed notonly on the position of the marker 50 in the most recent captured realimage, but also on the range near the position of the marker 50 in themost recent captured real image. For example, the design distinctionprocess may be performed multiple times while slightly shifting thepositions of the four vertices of the marker 50 detected from the mostrecent captured real image. Then, among these results, the positions ofthe four vertices having the highest degree of similarity to the patterndefinition data may be determined as the positions of the four verticesof the marker 50 in the current captured real image.

It should be noted that in the present embodiment, when the detection ofthe contour and the vertices of the marker 50 in the current capturedreal image has failed, the design distinction process is performed onthe current captured real image on the basis of the positions of thevertices (or the sample points) of the marker 50 detected from the mostrecent captured real image; however, the present invention is notlimited to this. Alternatively, the design distinction process may beperformed on the current captured real image on the basis of thepositions of the vertices (or the sample points) of the marker 50detected from another given captured real image obtained prior to thecurrent captured real image (i.e., on the basis of marker positioninformation corresponding to another given captured real image, theinformation already stored in the main memory 32).

It should be noted that in the present embodiment, when the detection ofthe contour and the vertices of the marker 50 in the current capturedreal image has failed, the design distinction process is performed onthe current captured real image on the basis of the positions of thevertices (or the sample points) of the marker 50 detected from the mostrecent captured real image. Such a process is not limited to the case ofperforming the design distinction process using the pattern matchingtechnique shown in FIGS. 48 through 60, but is also effective in thecase of performing the design distinction process using another givenknown pattern matching technique.

(Marker Position Correction Process)

Next, the marker position correction process is described. The markerposition correction process is a process of appropriately correcting theposition of the marker 50 detected in the design distinction process(i.e., the positions of the four vertices of the black area of themarker 50).

Before specifically describing the marker position correction process,first, a description is given of problems that may arise if the markerposition correction process is not performed.

As described above, the position of the marker 50 in the captured realimage is detected on the basis of the result of the contour detectionprocess performed on the captured real image. In the contour detectionprocess, edge pixels are detected by comparing the edge determinationthreshold to the luminance value of each pixel. Here, when a pixel ispresent that has a luminance value very close to the edge determinationthreshold, the pixel may be, for example, determined as a black area ina captured real image, and then determined as a white area in the nextcaptured real image. This can occur even when the camera (i.e., the gameapparatus 10) has not been moved at all. This is because the luminancevalue of each pixel can slightly vary over time due, for example, toenvironmental light. When the results of the contour detection processvary, the position of the marker 50 ultimately detected in the capturedreal image also varies. Accordingly, for example, the position and theorientation of the virtual object 60 shown in FIG. 4 vary even thoughthe user has not moved the game apparatus 10. That is, the virtual spaceimage seems to deviate. To prevent (or reduce) such an unfavorablephenomenon, in the present embodiment, the marker position correctionprocess is performed.

In the marker position correction process, first, the amount of movementof the marker 50 in the captured real image is calculated on the basisof the position of the marker 50 detected from the most recent capturedreal image and the position of the marker 50 detected from the currentcaptured real image. With reference to FIG. 63, a description is givenof an example of the calculation method of the amount of movement of themarker 50 in the captured real image.

As shown in FIG. 63, the upper left vertex of the marker 50 detectedfrom the most recent captured real image is Vp1; the lower left vertexis Vp2; the lower right vertex is Vp3; and the upper right vertex isVp4. The upper left vertex of the marker 50 detected from the currentcaptured real image is Vc1; the lower left vertex is Vc2; the lowerright vertex is Vc3; and the upper right vertex is Vc4. Then, thedistance between Vp1 and Vc1 is a; the distance between Vp2 and Vc2 isb; the distance between Vp3 and Vc3 is c; and the distance between Vp4and Vc4 is d. In this case, the amount of movement of the marker 50 inthe captured real image is â2+b̂2+ĉ2+d̂2 (“̂” represents power).

It should be noted that the calculation method described above is merelyillustrative, and the calculation method of the amount of movement ofthe marker 50 in the captured real image is not limited to this.

When the amount of movement of the marker 50 in the captured real imagehas been calculated, subsequently, the position of the marker 50detected in the design distinction process is corrected on the basis ofthe calculated amount of movement. With reference to FIG. 64, adescription is given of the correction method of the position of themarker 50.

When the amount of movement of the marker 50 is less than D1, thepositions of the vertices Vc (Vc1 through Vc4 shown in FIG. 63) of themarker 50 in the current captured real image are corrected to thepositions of the vertices Vp (Vp1 through Vp4 shown in FIG. 63) thathave been previously detected. It should be noted that D1 is apredetermined threshold, and as described later, the value of D1 variesdepending on the size of the marker 50 in the captured real image.

When the amount of movement of the marker 50 is D1 or greater but lessthan D2, the positions of the vertices Vc (Vc1 through Vc4 shown in FIG.63) of the marker 50 in the current captured real image are corrected tothe positions calculated by Vp×A+Vc×(1−A). It should be noted that D2 isa predetermined threshold greater than D1, and as described later, thevalue of D2 varies depending on the size of the marker 50 in thecaptured real image. Further, A is a predetermined value greater than 0but less than 1, and as described later, the value of A varies dependingon the motion vector of the marker 50.

When the amount of movement of the marker 50 is D2 or greater, thepositions of the vertices Vc (Vc1 through Vc4 shown in FIG. 63) of themarker 50 in the current captured real image are not corrected.

As described above, when the amount of movement of the marker 50 is lessthan D1 (i.e., the amount of movement of the marker 50 is very small),it is determined that the marker 50 has not moved at all from theposition of the marker 50 in the most recent captured real image.Accordingly, it is possible to prevent an unintended change in theposition of the marker, and consequently, it is possible to prevent adeviation in the virtual space image.

In addition, when the amount of movement of the marker 50 is D1 orgreater but less than D2 (i.e., the amount of movement of the marker 50is small), as shown in FIG. 65, the position of the marker 50 iscorrected to a position on the line segments connecting the position ofthe marker 50 in the most recent captured real image to the position ofthe marker 50 in the current captured real image (i.e., pointsinternally dividing the line segments connecting Vp to Vc, respectively,in a ratio of (1−A):A). Accordingly, it is possible to reduce anunintended change in the position of the marker as described above, andconsequently, it is possible to reduce a deviation in the virtual spaceimage. Further, unlike the case where the amount of movement of themarker 50 is less than D1, the corrected position of the marker 50 is aposition closer to the position of the marker 50 in the current capturedreal image than to the position of the marker 50 in the most recentcaptured real image. Thus, when the user has moved the game apparatus 10by a small amount (or slowly), the position of the marker 50 (i.e., theposition of the virtual object 60) is updated in accordance with themotion of the game apparatus 10, while reducing an unintended change inthe position of the marker.

It should be noted that when the amount of movement of the marker 50 isD2 or greater (i.e., when the amount of movement of the marker 50 islarge), the position of the marker 50 is not corrected. Accordingly,when the user has moved the game apparatus 10 rapidly by a large amount,the position of the marker 50 is updated in immediate response to such arapid motion of the game apparatus 10. Thus, for example, the virtualobject 60 shown in FIG. 4 is not displayed so as to be shiftedsignificantly from the marker 50.

Next, a description is given of the determination method of thethresholds D1 and D2 described above.

As described above, the thresholds D1 and D2 are thresholds fordetermining the level of the amount of movement of the marker 50 in thecaptured real image (i.e., very small, small, or large), and thesethresholds are preferably changed depending on the size of the marker 50in the captured real image. With reference to FIGS. 66 and 67, thereason for this is explained below.

FIG. 66 is an example where the virtual object 60 is displayed at themost recent position of the marker when the size of the marker 50 in thecaptured real image is large (i.e., when the position of the marker 50is close to the camera in the real world). Here, the distance (thedistance in the captured real image) between the most recent position ofthe marker and the current position of the marker is D. In this case, itseems to the user that the virtual object 60 is not shiftedsignificantly from the current position of the marker.

FIG. 67 is an example where the virtual object 60 is displayed at themost recent position of the marker (i.e., the position of the marker 50in the most recent captured real image) when the size of the marker 50in the captured real image is small (i.e., when the position of themarker 50 is far from the camera in the real world). Here, the distance(the distance in the captured real image) between the most recentposition of the marker and the current position of the marker is also D,as in FIG. 66. In this case, it seems to the user that the virtualobject 60 is shifted significantly from the current position of themarker.

As is clear from FIGS. 66 and 67, even when the distance (the distancein the captured real image) between the most recent position of themarker and the current position of the marker is the same, it seems tothe user that the smaller the size of the marker 50 in the captured realimage is, the more significantly the most recent position of the markeris shifted from the current position of the marker.

In response, as shown in FIG. 68, it is preferable that the value of D1should be increased when the size of the marker 50 in the captured realimage is large, and the value of D1 should be decreased when the size ofthe marker 50 in the captured real image is small. That is, it ispreferable that the smaller the size of the marker 50 in the capturedreal image, the smaller the value of the D1.

Similarly, as shown in FIG. 69, it is preferable that the value of D2should be increased when the size of the marker 50 in the captured realimage is large, and the value of D2 should be decreased when the size ofthe marker 50 in the captured real image is small. That is, it ispreferable that the smaller the size of the marker 50 in the capturedreal image, the smaller the value of D2.

It should be noted that various possible methods can be used as thecalculation method of the size of the marker 50 in the captured realimage. For example, the area of the marker 50 in the captured real imagemay be calculated as the size of the marker 50 in the captured realimage. In another embodiment, the size of the cross product of the twodiagonals of the marker 50 in the captured real image may be calculatedas the size of the marker 50 in the captured real image. In yet anotherembodiment, the diameter of a circle including the four vertices of themarker 50 in the captured real image may be calculated as the size ofthe marker 50 in the captured real image. In yet another embodiment, thesize of the marker 50 in the captured real image may be calculated onthe basis of the width in the X-axis direction and the width in theY-axis direction of the marker 50 in the captured real image.

Next, a description is given of the determination method of thepredetermined value A.

As described above, when the amount of movement of the marker 50 is D1or greater but less than D2, the position of the marker 50 is, as shownin FIG. 65, corrected to the points internally dividing, in a ratio of(1−A):A, the line segments connecting the position of the marker 50 inthe most recent captured real image to the position of the marker 50 inthe current captured real image.

Here, when the value of A is fixed to a small value (e.g., 0.1), theposition of the marker 50 is corrected to almost the same position asthe position of the marker 50 in the most recent captured real image.Accordingly, the responsiveness decreases, and even when the position ofthe marker 50 in the captured real image changes, the position of thevirtual object 60 does not significantly change. Thus, a problem ariseswhere, for example, when the user has moved the game apparatus 10 slowlyand continuously in a desired direction, the virtual object 60 seems tobe clearly shifted from the marker 50.

Conversely, when the value of A is fixed to a large value (e.g., 0.9),the position of the marker 50 is corrected to almost the same positionas the position of the marker 50 in the current captured real image.Accordingly, although the responsiveness increases, a problem ariseswhere the effect of reducing an unintended change in the position of themarker as described above is greatly impaired.

In the present embodiment, to solve both of the above two problems, thevalue of A is varied in accordance with the motion vector of the marker50.

Specifically, on the basis of the position of the marker 50 in acaptured real image (e.g., the positions of the vertices of the marker50) and the position of the marker 50 in the most recent captured realimage, motion vectors indicating in which direction the marker 50 hasmoved are sequentially calculated and sequentially stored in the mainmemory 32. Then, on the basis of a newly calculated motion vector and amotion vector calculated in the past and stored in the main memory 32,it is determined whether or not the marker 50 is continuously moving ina constant direction (which may be a generally constant direction) inthe captured real image. When the marker 50 is continuously moving in aconstant direction, the value of A is increased. If not, the value of Ais decreased.

The variation of the value of A as described above improves theresponsiveness, for example, while the user is moving the game apparatus10 slowly in a desired direction. Accordingly, the virtual object 60does not seem to be shifted significantly from the marker 50. Further,the responsiveness decreases in other situations, and therefore, theeffect of reducing an unintended change in the position of the marker asdescribed above is sufficiently exerted.

It should be noted that in the present embodiment, as shown in FIG. 64,the correction method of the position of the marker 50 (e.g., thepositions of the four vertices) is switched between: the case where theamount of movement of the marker 50 is less than D1; the case where theamount of movement of the marker 50 is D1 or greater but less than D2;and the case where the amount of movement of the marker 50 is D2 orgreater. This is, however, merely illustrative, and the correctionmethod of the position of the marker 50 is not limited to this. Forexample, as another embodiment, as shown in FIG. 70, when the amount ofmovement of the marker 50 is less than D3, the position of the marker 50detected on the basis of the current captured real image may becorrected to the position of the marker 50 in the most recent capturedreal image. When the amount of movement of the marker 50 is D3 orgreater, the position of the marker 50 detected on the basis of thecurrent captured real image may be used as it is without beingcorrected. This makes it possible to prevent an unintended change in theposition of the marker. It should be noted that D3 is a predeterminedthreshold, and therefore, the value of D3 may vary in accordance withthe size of the marker 50 in the captured real image.

In addition, as yet another embodiment, as shown in FIG. 71, when theamount of movement of the marker 50 is less than D4, the position of themarker 50 detected on the basis of the current captured real image maybe corrected to the points internally dividing, in a ratio of (1−A):A,the line segments connecting the position of the marker 50 in the mostrecent captured real image to the position of the marker 50 in thecurrent captured real image. When the amount of movement of the marker50 is D4 or greater, the position of the marker 50 detected on the basisof the current captured real image may be used as it is without beingcorrected. This makes it possible to reduce an unintended change in theposition of the marker. It should be noted that D4 is a predeterminedthreshold, and therefore, the value of D4 may vary in accordance withthe size of the marker 50 in the captured real image.

It should be noted that the marker position correction process is, asdescribed above, performed using the amount of movement of the marker 50and the motion vector of the marker 50. However, when a plurality ofmarkers of the same design are included in the captured real image, itis necessary to determine where each marker has moved to. For example,as shown in FIG. 72, when a plurality of markers (a marker A and amarker B) of the same design as each other have been detected from themost recent captured real image and a plurality of markers (a firstmarker and a second marker) of the same design as the above have beendetected from the current captured real image, it is necessary todetermine the correspondence relationships between the markers.

In the present embodiment, the distance between a representative pointof each marker detected from the most recent captured real image and arepresentative point of the corresponding marker detected from thecurrent captured real image is calculated. When the distance is smallerthan a predetermined threshold, it is determined that the two markerscorrespond to each other. As a representative point of each marker, forexample, the coordinates obtained by averaging the coordinates of thefour vertices of the marker can be used.

A specific description is given with reference to FIG. 72. First, thedistance between the representative point of the marker A and therepresentative point of the first marker is calculated. When thedistance is smaller than a predetermined threshold (it is preferablethat the larger the size of the marker A or the first marker in thecaptured real image, the greater the threshold), it is determined thatthe marker A and the first marker correspond to each other.

Similarly, the distance between the representative point of the marker Aand the representative point of the second marker is calculated. Whenthe distance is smaller than a predetermined threshold (it is preferablethat the larger the size of the marker A or the second marker in thecaptured real image, the greater the threshold), it is determined thatthe marker A and the second marker correspond to each other.

Yet similarly, the distance between the representative point of themarker B and the representative point of the first marker is calculated.When the distance is smaller than a predetermined threshold (it ispreferable that the larger the size of the marker B or the first markerin the captured real image, the greater the threshold), it is determinedthat the marker B and the first marker correspond to each other.

Yet similarly, the distance between the representative point of themarker B and the representative point of the second marker iscalculated. When the distance is smaller than a predetermined threshold(it is preferable that the larger the size of the marker B or the secondmarker in the captured real image, the greater the threshold), it isdetermined that the marker B and the second marker correspond to eachother.

The determinations of the correspondence relationships between themarkers as described above make it possible that even when a pluralityof markers of the same design are included in the captured real image,the amount of movement and the motion vector of each marker arecalculated.

It should be noted that when a plurality of markers of different designsare included in the captured real image, it is possible to determine thecorrespondence relationships between the markers on the basis of thedesigns.

It should be noted that in the marker position correction processdescribed above, the amount of movement of the marker 50 in the capturedreal image is calculated on the basis of the position of the marker 50detected from the most recent captured real image and the position ofthe marker 50 detected from the current captured real image; however,the present invention is not limited to this. Alternatively, forexample, the amount of movement of the marker 50 in the captured realimage may be calculated on the basis of the position of the marker 50detected from a given captured real image acquired prior to the currentcaptured real image (e.g., a captured real image acquired two imagesbefore the current captured real image) and the position of the marker50 detected from the current captured real image.

As described above, the position of the marker 50 (e.g., the positionsof the four vertices of the black area of the marker 50) is detectedfrom the captured real image through the contour detection process, thevertex detection process, the rough distinction process, the designdistinction process, and the marker position correction process. Then,the positional relationship between the camera (the outer capturingsection (left) 23 a or the outer capturing section (right) 23 b) and themarker 50 in real space is calculated on the basis of the position ofthe marker 50 thus detected. The positional relationship between thevirtual camera and the virtual object 60 in the virtual space is set onthe basis of the calculation result. Then, the virtual space image isgenerated on the basis of the virtual camera, the virtual space image iscombined with a captured real image captured by the camera, and thecombined image is displayed on the upper LCD 22.

Next, a specific description is given of the flow of the imagerecognition process performed by the CPU 311 on the basis of the imagerecognition program.

FIG. 73 shows programs and data stored in the main memory 32.

The main memory 32 stores an image recognition program 70, an imagegeneration program 71, virtual object data 72, virtual camera data 73,pattern definition data 74, captured real image data 75, an edgedetermination threshold 76, edge pixel information 77, straight lineinformation 78, vertex information 78, marker position information 80,motion vector information 81, and various variables 82.

The image recognition program 70 is a computer program for detecting amarker from a captured real image. The image generation program 71 is acomputer program for combining the captured real image with a virtualspace image on the basis of the position of the marker detected on thebasis of the image recognition program. These programs may be loadedinto the main memory 32 from the data storage internal memory 35, or maybe loaded into the main memory 32 from the external memory 44, or may beloaded into the main memory 32 from a server device or another gameapparatus through the wireless communication module 36 or the localcommunication module 37. It should be noted that the image generationprocess performed by the CPU 311 on the basis of the image generationprogram 71 may use a known technique, and has little relevance to thepresent invention, and therefore is not described in detail in thepresent specification. Further, the image recognition program 70 and theimage generation program 71 may be configured as one image processingprogram.

The virtual object data 72 is data concerning, for example, the shape,the color, and the pattern of the virtual object 60 placed in thevirtual space.

The virtual camera data 73 is data concerning, for example, the positionand the orientation of the virtual camera placed in the virtual space.

The pattern definition data 74 is data indicating the design of themarker 50, the data used to distinguish the marker 50 and stored inadvance (FIG. 49).

The captured real image data 75 is image data of a captured real imagecaptured by the camera (the outer capturing section (left) 23 a or theouter capturing section (right) 23 b).

The edge determination threshold 76 is a threshold for, in the contourdetection process, determining whether or not each pixel of the capturedreal image is an edge pixel.

The edge pixel information 77 is information about a pixel determined asan edge pixel in the contour detection process.

The straight line information 78 is information about a straight linegenerated or updated in the straight line calculation process.

The vertex information 78 is information about a vertex calculated inthe vertex calculation process.

The marker position information 80 is information indicating theposition of the marker 50 (the positions of the four vertices of theblack area of the marker 50) in the captured real image, the informationgenerated in the vertex detection process and updated where necessary inthe marker position correction process. The marker position information80 includes not only information (80 a) indicating the position of themarker 50 detected from the current captured real image, but alsoinformation (80 b) indicating the position of the marker 50 detectedfrom the most recent captured real image.

The motion vector information 81 is information indicating the motionvector indicating the direction in which the marker 50 has moved.

The various variables 82 are various variables (e.g., the white arealuminance value Lw, the black area luminance value Lb, the threshold D1,the threshold D2, and the predetermined value A) used when the imagerecognition program 70 and the image generation program 71 are executed.

First, with reference to FIG. 74, a description is given of the overallflow of the image recognition process performed by the CPU 311 on thebasis of the image recognition program.

In step S1, the CPU 311 acquires a captured real image captured by thecamera (the outer capturing section (left) 23 a or the outer capturingsection (right) 23 b), and stores the acquired captured real image inthe main memory 32.

In step S2, the CPU 311 performs the contour detection process. Aspecific flow of the contour detection process will be described laterwith reference to FIG. 75.

In step S3, the CPU 311 determines whether or not the contour has beendetected in the contour detection process in step S2. When the contourhas been detected, the processing proceeds to step S4. If not, theprocessing proceeds to step S9.

In step S4, the CPU 311 performs the vertex detection process. Aspecific flow of the vertex detection process will be described laterwith reference to FIG. 76.

In step S5, the CPU 311 determines whether or not the vertices have beendetected in the vertex detection process in step S4. When the verticeshave been detected, the processing proceeds to step S6. If not, theprocessing proceeds to step S9.

In step S6, the CPU 311 performs the rough distinction process. Aspecific flow of the rough distinction process will be described laterwith reference to FIG. 77.

In step S7, on the basis of the result of the rough distinction processin step S6, the CPU 311 determines whether or not vertices to becandidates for the marker 50 are present. When vertices to be candidatesfor the marker 50 have been detected, the processing proceeds to stepS8. If not, the processing proceeds to step S12.

In step S8, the CPU 311 performs the design distinction process. Aspecific flow of the design distinction process will be described laterwith reference to FIG. 78.

In step S9, the CPU 311 performs the design distinction process on thebasis of the position of the marker 50 in the most recent captured realimage (i.e., the positions of the vertices detected in the most recentcaptured real image or the positions of the sample points determined inthe most recent captured real image).

In step S10, the CPU 311 determines whether or not the marker 50 hasbeen detected in the design distinction process in step S8 or step S9.When the marker 50 has been detected, the processing proceeds to stepS11. If not, the processing proceeds to step S12.

In step S11, the CPU 311 performs the marker position correctionprocess. A specific flow of the marker position correction process willbe described later with reference to FIG. 79.

In step S12, the CPU 311 determines whether or not the image recognitionprocess is to be ended. When the image recognition process is to becontinued, the processing returns to step S1. When the image recognitionprocess is to be ended, the CPU 311 ends the execution of the imagerecognition program.

Next, with reference to FIG. 75, a description is given of the flow ofthe contour detection process performed by the CPU 311 on the basis ofthe image recognition program.

In step S21, the CPU 311 determines the marked pixel P(n).

In step S22, the CPU 311 determines whether or not L(n−8) L(n) is 60 orgreater. When L(n−8) L(n) is 60 or greater, the processing proceeds tostep S23. If not, the processing proceeds to step S34.

In step S23, the CPU 311 assigns 8 to a variable k as an initial value.

In step S24, the CPU 311 determines whether or not L(n−k−1) is smallerthan L(n−k). When L(n−k−1) is smaller than L(n−k), the processingproceeds to step S25. If not, the processing proceeds to step S26.

In step S25, the CPU 311 increments the variable k.

In step S26, the CPU 311 determines that L(n−k) is the white arealuminance value Lw.

In step S27, the CPU 311 determines whether or not L(n) is smaller thanL(n+2). When L(n) is smaller than L(n+2), the processing proceeds tostep S28. If not, the processing proceeds to step S30.

In step S28, the CPU 311 determines whether or not Lw−L(n+2) is 60 orgreater. When Lw−L(n+2) is 60 or greater, the processing proceeds tostep S29. If not, the processing proceeds to step S30.

In step S29, the CPU 311 determines that L(n+2) is the black arealuminance value Lb.

In step S30, the CPU 311 determines that L(n) is the black arealuminance value Lb.

In step S31, the CPU 311 determines that the average value of Lw and Lbis the edge determination threshold.

In step S32, the CPU 311 detects the starting edge pixel on the basis ofthe edge determination threshold. The coordinates of the starting edgepixel are stored in the main memory 32 as edge pixel information.

In step S33, the CPU 311 performs the edge tracking process ofsequentially tracking adjacent edge pixels such that the starting pointis the starting edge pixel. The coordinates of the edge pixelssequentially detected in the edge tracking process are sequentiallystored in the main memory 32 as edge pixel information.

In step S34, the CPU 311 determines whether or not a next marked pixelis present. When a next marked pixel is present, the processing returnsto step S21. If not (i.e., when the processes on all the marked pixelcandidates in the captured real image are completed), the contourdetection process is ended.

Next, with reference to FIG. 76, a description is given of the flow ofthe vertex detection process performed by the CPU 311 on the basis ofthe image recognition program.

In step S41, the CPU 311 generates a first straight line (i.e., astraight line Li(0-5) corresponding to a vector V(0-5) connecting from astarting edge pixel Pe(0) to an edge pixel Pe (5)), and stores dataindicating the straight line in the main memory 32.

In step S42, the CPU 311 determines whether or not the generatedstraight line and a vector following the straight line are placed on thesame straight line, the determination made on the basis of the angle ofthe vector with respect to the straight line (see FIG. 24). When it isdetermined that the straight line and the vector are placed on the samestraight line, the processing proceeds to step S43. If not, theprocessing proceeds to step S44.

In step S43, the CPU 311 updates the straight line. Specifically, on thebasis of sample edge pixels included from the rear end of the straightline to the head of the vector, the CPU 311 calculates the straight lineby a least squares method, and updates the straight line in accordancewith the calculation result (i.e., updates the data indicating thestraight line stored in the main memory 32).

In step S44, on the basis of the angle of the vector with respect to thestraight line, the CPU 311 determines whether or not the black area hasa convex angle at the intersection of the straight line and the vectorfollowing the straight line (see FIG. 24). When it is determined thatthe black area has a convex angle, the processing proceeds to step S45.If not, the processing proceeds to step S47.

In step S45, the CPU 311 newly generates a straight line correspondingto the vector, and newly stores data indicating the newly generatedstraight line in the main memory 32.

In step S46, the CPU 311 determines whether or not a circuit of thecontour of the black area has been completed (i.e., the detection hasreturned to the starting edge pixel). When a circuit has been completed,the processing proceeds to step S49. If not, the processing returns tostep S42.

In step S47, the CPU 311 determines whether or not the straight linecalculation process (i.e., the processes of steps S42 through S46) isbeing performed counterclockwise. When the straight line calculationprocess is being performed counterclockwise, the processing proceeds tostep S48. If not, the processing proceeds to step S49. It should benoted that in the present embodiment, the straight line calculationprocess is started counterclockwise first.

In step S48, the CPU 311 switches the straight line calculation processfrom counterclockwise to clockwise.

In step S49, on the basis of data representing the plurality of straightlines stored in the main memory 32, the CPU 311 determines whether ornot, among the plurality of straight lines, a plurality of straightlines placed on the same straight line and directed in the samedirection are present. When a plurality of straight lines placed on thesame straight line and directed in the same direction are present, theprocessing proceeds to step S50. If not, the processing proceeds to stepS51.

In step S50, the CPU 311 integrates the plurality of straight linesplaced on the same straight line and directed in the same direction intoone straight line, and updates the data concerning the plurality ofstraight lines stored in the main memory 32.

In step S51, on the basis of the data concerning the plurality ofstraight lines stored in the main memory 32, the CPU 311 selects fourstraight lines from among the plurality of straight lines. Specifically,the CPU 311 calculates the length of each straight line, and selects thelongest straight line, the second longest straight line, the thirdlongest straight line, and the fourth longest straight line.

In step S52, the CPU 311 calculates the positions of the four verticesof the black area by calculating the positions of the intersections ofthe four straight lines. Then, the CPU 311 stores the positions of thefour vertices in the main memory 32, and ends the vertex detectionprocess.

Next, with reference to FIG. 77, a description is given of the flow ofthe rough distinction process performed by the CPU 311 on the basis ofthe image recognition program.

In step S61, the CPU 311 determines whether or not the four verticesdetected in the vertex detection process satisfy the exclusion conditionA. The exclusion condition A is, as described above, the case where thedistance between any two adjacent vertices is too small. When theexclusion condition A is satisfied, the processing proceeds to step S65.If not, the processing proceeds to step S62.

In step S62, the CPU 311 determines whether or not the four verticesdetected in the vertex detection process satisfy the exclusion conditionB. The exclusion condition B is, as described above, the case where thedistance between any vertex and either one of the two sides not adjacentto the vertex is too small. When the exclusion condition B is satisfied,the processing proceeds to step S65. If not, the processing proceeds tostep S63.

In step S63, the CPU 311 determines whether or not the four verticesdetected in the vertex detection process satisfy the exclusion conditionC. The exclusion condition C is, as described above, the case where thestraight lines of any two opposing sides are directed in generally thesame direction. When the exclusion condition. C is satisfied, theprocessing proceeds to step S65. If not, the processing proceeds to stepS64.

In step S64, the CPU 311 determines whether or not the four verticesdetected in the vertex detection process satisfy the exclusion conditionD. The exclusion condition D is, as described above, the case where aconcave angle is included. When the exclusion condition D is satisfied,the processing proceeds to step S65. If not, the rough distinctionprocess is ended.

In step S65, the CPU 311 excludes the four vertices detected in thevertex detection process from process objects in the design distinctionprocess (e.g., deletes data concerning the four vertices from the mainmemory 32). Then, the rough distinction process is ended.

Next, with reference to FIG. 78, a description is given of the flow ofthe design distinction process performed by the CPU 311 on the basis ofthe image recognition program.

In step S71, the CPU 311 selects any two opposing sides from among thefour sides of the rectangle surrounded by the four vertices detected inthe vertex detection process.

In step S72, the CPU 311 determines whether or not the two sidesselected in step S71 are parallel (including the case where they aregenerally parallel) to each other. When the two sides are parallel toeach other, the processing proceeds to step S73. If not, the processingproceeds to step S74.

In step S73, the CPU 311 divides each of the two sides selected in stepS71 into 16 equal parts.

In step S74, the CPU 311 divides each of the two sides selected in stepS71 into 16 unequal parts (e.g., by the method shown in FIGS. 53 through55).

In step S75, the CPU 311 selects the two opposing sides that have notbeen selected in step S71, from among the four sides of the rectanglesurrounded by the four vertices detected in the vertex detectionprocess.

In step S76, the CPU 311 determines whether or not the two sidesselected in step S75 are parallel (including the case where there aregenerally parallel) to each other. When the two sides are parallel toeach other, the processing proceeds to step S77. If not, the processingproceeds to step S78.

In step S77, the CPU 311 divides each of the two sides selected in stepS75 into 16 equal parts.

In step S78, the CPU 311 divides each of the two sides selected in stepS75 into 16 unequal parts (e.g., by the method shown in FIGS. 53 through55).

In step S79, on the basis of the pixel values of the sample pointsdetermined by dividing the four sides of the rectangle surrounded by thefour vertices detected in the vertex detection process and the basis ofthe pixel values of the sample points defined in the pattern definitiondata, the CPU 311 calculates correlation coefficients representing thedegrees of similarity between the pixel values.

In step S80, on the basis of the correlation coefficients calculated instep S79, the CPU 311 determines whether or not the design displayed inthe area surrounded by the four vertices detected in the vertexdetection process coincides with the design of the marker 50. When thedesigns coincide with each other, the processing proceeds to step S81.If not, the design distinction process is ended.

In step S81, the CPU 311 stores, as marker position information in themain memory 32, the coordinates of the four vertices (the upper leftvertex, the lower left vertex, the lower right vertex, and the upperright vertex) of the marker 50 in the captured real image.

Next, with reference to FIG. 79, a description is given of the flow ofthe marker position correction process performed by the CPU 311 on thebasis of the image recognition program.

In step S91, the CPU 311 calculates the size of the marker 50 in thecaptured real image, and stores the calculation result in the mainmemory 32.

In step S92, the CPU 311 determines whether or not the same marker asthat detected from the current captured real image has been present inthe most recent captured real image. When the same marker has beenpresent, the processing proceeds to step S93. If not, the markerposition correction process is ended (i.e., the position of the markerdetected from the current captured real image is used as it is withoutbeing corrected). It should be noted that the determination of whetheror not the same marker as that detected from the current captured realimage has been present in the most recent captured real image can bemade, for example, on the basis of the size of the marker 50 calculatedin step S91 and by the method as described with reference to FIG. 72.

In step S93, on the basis of the size of the marker 50 calculated instep S91, the CPU 311 calculates the thresholds D1 and D2 (FIGS. 68 and69), and stores the calculated thresholds D1 and D2 in the main memory32.

In step S94, the CPU 311 determines whether or not the amount ofmovement of the marker 50 is less than D1. When the amount of movementof the marker 50 is less than D1, the processing proceeds to step S95.If not, the processing proceeds to step S96.

In step S95, the CPU 311 corrects the position of the marker 50 detectedin the design distinction process to the position of the marker that hasbeen previously detected. Then, the marker position correction processis ended.

In step S96, the CPU 311 determines whether or not the amount ofmovement of the marker 50 is less than D2. When the amount of movementof the marker 50 is less than D2, the processing proceeds to step S97.If not, the marker position correction process is ended (i.e., theposition of the marker detected from the current captured real image isused as it is without being corrected).

In step S97, the CPU 311 calculates the motion vector of the marker 50,and determines the predetermined value A on the basis of the motionvector and a motion vector calculated in the past. Specifically, on thebasis of these motion vectors, the CPU 311 determines whether or not themarker 50 is continuously moving in a constant direction in the capturedreal image. When the marker 50 is continuously moving in a constantdirection, the value of A is increased. If not, the value of A isdecreased. The motion vector calculated in this process is stored in themain memory 32 as the motion vector information 81.

In step S98, the CPU 311 corrects the position of the marker 50 to thepoints internally dividing, in a ratio of (1−A):A, the line segmentsconnecting the position of the marker 50 in the most recent capturedreal image to the position of the marker 50 in the current captured realimage. Then, the marker position correction process is ended.

(Variations)

It should be noted that in the above embodiment, specific processingmethods are described for: (1) the contour detection process; (2) thevertex detection process; (3) the rough distinction process; (4) thedesign distinction process; and (5) the marker position correctionprocess. Alternatively, one or more of these processes may be replacedwith known techniques.

In addition, an image serving as a process object of the imagerecognition process is not limited to captured real images sequentiallyacquired in real time from the camera. Alternatively, for example, theimage may be an image captured by the camera in the past and stored inthe data storage internal memory 35 or the like, or may be an imagereceived from another device, or may be an image acquired through anexternal storage medium.

In addition, a recognition object of the image recognition process isnot limited to the black area of the marker 50. The recognition objectmay be a given object (e.g., a person's face or hand), or a givendesign, included in an image.

In addition, the result of the image recognition process can be used notonly in AR technology, but also in another given application.

In addition, in the present embodiment, image processing (the imagerecognition process and the image generation process) is performed bythe game apparatus 10; however, the present invention is not limited tothis. Alternatively, image processing may be performed by a giveninformation processing apparatus (or a given information processingsystem) such as a stationary game apparatus, a personal computer, and amobile phone.

In addition, in the present embodiment, the image processing isperformed by one game apparatus 10. Alternatively, in anotherembodiment, the image processing may be performed by a plurality ofinformation processing apparatuses capable of communicating with oneanother in a shared manner.

In addition, in the present embodiment, the image recognition programand the like are performed by one CPU 311. Alternatively, in anotherembodiment, the image recognition program and the like may be performedby a plurality of CPUs 311 in a shared manner.

In addition, in the present embodiment, the image processing isperformed by the CPU 311 on the basis of the image recognition programand the like. Alternatively, in another embodiment, part of the imageprocessing may be achieved by hardware, instead of the CPU 311.

In addition, in the above embodiment, a captured real image captured bythe camera is combined with a virtual space image, and the combinedimage is displayed on the upper LCD 22 (a video see-through method).Alternatively, instead of the video see-through method, an opticalsee-through method may be employed in which a virtual object isdisplayed on a transmissive display screen so that a user views an imageas if the virtual object actually exists in a real world that is visiblethrough the transmissive display screen.

While the invention has been described in detail, the foregoingdescription is in all aspects illustrative and not restrictive. It willbe understood that numerous other modifications and variations can bedevised without departing from the scope of the invention.

1. A computer-readable storage medium having stored thereon an imagerecognition program causing a computer of an information processingapparatus to function as: image acquisition means for acquiring animage; vertex detection means for detecting from the image a pluralityof vertices of a contour of an object or of a design; division pointgeneration means for generating a predetermined number of divisionpoints on each of sides connecting the plurality of vertices to eachother, so as to divide each side of at least one pair of two opposingsides into unequal parts; sample point determination means fordetermining a plurality of sample points on the basis of straight linesconnecting the division points on the two opposing sides to one another;and distinction means for, on the basis of pixel values of the samplepoints, determining whether or not a predetermined object or design isdisplayed in an area surrounded by the plurality of vertices in theimage.
 2. The computer-readable storage medium according to claim 1,wherein the division point generation means generates the divisionpoints on each side of at least one pair of two opposing sides such thatthe closer to one end of each side of the two opposing sides, the denserthe division points.
 3. The computer-readable storage medium accordingto claim 1, wherein the division point generation means divides eachside of at least one pair of two opposing sides into unequal parts inaccordance with a ratio of a distance between one end of one side of thetwo opposing sides and a corresponding one end of the other side; to adistance between the other ends.
 4. The computer-readable storage mediumaccording to claim 1, the image recognition program further causing thecomputer to function as: determination means for determining whether ornot, among the plurality of sides connecting the plurality of verticesto each other, given two opposing sides are parallel to each other,wherein the division point generation means includes: equal divisionmeans for, when the determination means has determined that any twoopposing sides are parallel to each other, generating the divisionpoints so as to divide each side of the two opposing sides into equalparts; and unequal division means for, when the determination means hasdetermined that any two opposing sides are not parallel to each other,generating the division points so as to divide each side of the twoopposing sides into unequal parts.
 5. The computer-readable storagemedium according to claim 1, wherein the division point generation meansincludes: first vanishing point calculation means for calculating afirst vanishing point, the first vanishing point being an intersectionof straight lines extending from a first side and a second side,respectively, the first side and the second side opposing each other;second vanishing point calculation means for calculating a secondvanishing point, the second vanishing point being an intersection ofstraight lines extending from a third side and a fourth side,respectively, the third side and the fourth side opposing each other;second straight line calculation means for calculating a second straightline, the second straight line being parallel to a first straight lineconnecting the first vanishing point to the second vanishing point, thesecond straight line passing through the vertex furthest from the firststraight line; first equal division means for, on a line segmentconnecting an intersection of the straight line passing through thefirst side and the second straight line to an intersection of thestraight line passing through the second side and the second straightline, generating a plurality of first equal division points so as todivide the line segment into equal parts; second equal division meansfor, on a line segment connecting an intersection of the straight linepassing through the third side and the second straight line to anintersection of the straight line passing through the fourth side andthe second straight line, generating a plurality of second equaldivision points so as to divide the line segment into equal parts; firstgeneration means for, on the basis of straight lines connecting thefirst vanishing point to the first equal division points, generating thedivision points on each of the third side and the fourth side so as todivide each of the third side and the fourth side into unequal parts;and second generation means for, on the basis of straight linesconnecting the second vanishing point to the second equal divisionpoints, generating the division points on each of the first side and thesecond side so as to divide each of the first side and the second sideinto unequal parts.
 6. The computer-readable storage medium according toclaim 1, wherein the image acquisition means repeatedly acquires images,and the vertex detection means detects the plurality of vertices fromthe images repeatedly acquired by the image acquisition means.
 7. Thecomputer-readable storage medium according to claim 1, wherein thedistinction means determines, by comparing the pixel values of thesample points with pixel values corresponding to the predeterminedobject or design that are stored in advance, whether or not thepredetermined object or design is displayed in the area surrounded bythe plurality of vertices in the image.
 8. An image recognitionapparatus comprising: image acquisition means for acquiring an image;vertex detection means for detecting from the image a plurality ofvertices of a contour of an object or of a design; division pointgeneration means for generating a predetermined number of divisionpoints on each of sides connecting the plurality of vertices to eachother, so as to divide each side of at least one pair of two opposingsides into unequal parts; sample point determination means fordetermining a plurality of sample points on the basis of straight linesconnecting the division points on the two opposing sides to one another;and distinction means for, on the basis of pixel values of the samplepoints, determining whether or not a predetermined object or design isdisplayed in an area surrounded by the plurality of vertices in theimage.
 9. An image recognition method comprising: an image acquisitionstep of acquiring an image; a vertex detection step of detecting fromthe image a plurality of vertices of a contour of an object or of adesign; a division point generation step of generating a predeterminednumber of division points on each of sides connecting the plurality ofvertices to each other, so as to divide each side of at least one pairof two opposing sides into unequal parts; a sample point determinationstep of determining a plurality of sample points on the basis ofstraight lines connecting the division points on the two opposing sidesto one another; and a distinction step of, on the basis of pixel valuesof the sample points, determining whether or not a predetermined objector design is displayed in an area surrounded by the plurality ofvertices in the image.
 10. An image recognition system comprising: imageacquisition means for acquiring an image; vertex detection means fordetecting from the image a plurality of vertices of a contour of anobject or of a design; division point generation means for generating apredetermined number of division points on each of sides connecting theplurality of vertices to each other, so as to divide each side of atleast one pair of two opposing sides into unequal parts; sample pointdetermination means for determining a plurality of sample points on thebasis of straight lines connecting the division points on the twoopposing sides to one another; and distinction means for, on the basisof pixel values of the sample points, determining whether or not apredetermined object or design is displayed in an area surrounded by theplurality of vertices in the image.
 11. An image recognition systemincluding an image recognition apparatus and a marker in which a designis drawn, the image recognition apparatus comprising: a capturingsection for capturing the marker; image acquisition means for acquiringan image from the capturing section; vertex detection means fordetecting from the image a plurality of vertices of a contour of themarker or of the design; division point generation means for generatinga predetermined number of division points on each of sides connectingthe plurality of vertices to each other, so as to divide each side of atleast one pair of two opposing sides into unequal parts; sample pointdetermination means for determining a plurality of sample points on thebasis of straight lines connecting the division points on the twoopposing sides to one another; and distinction means for, on the basisof pixel values of the sample points, determining whether or not apredetermined design is displayed in an area surrounded by the pluralityof vertices in the image.